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  • 51.
    Eriksson, Olof
    et al.
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Antaros Med AB, Uppsala, Sweden.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Akad Sjukhuset, Uppsala, Sweden.
    Haack, Torsten
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Bossart, Martin
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Laitinen, Iina
    Sanofi, Global Imaging, Frankfurt, Germany..
    Larsen, Philip J.
    Sanofi, Diabet Res, Frankfurt, Germany..
    Berglund, Jan Erik
    Clin Trial Consultants AB, Uppsala, Sweden..
    Antoni, Gunnar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi. Akad Sjukhuset, Uppsala, Sweden.
    Johansson, Lars
    Antaros Med AB, Uppsala, Sweden..
    Pierrou, Stefan
    Antaros Med AB, Uppsala, Sweden..
    Tillner, Joachim
    Sanofi, Translat Med, Frankfurt, Germany..
    Wagner, Michael
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Glucagonlike Peptide-1 Receptor Imaging in Individuals with Type 2 Diabetes2022Inngår i: Journal of Nuclear Medicine, ISSN 0161-5505, E-ISSN 1535-5667, Vol. 63, nr 5, s. 794-800Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    The glucagonlike peptide-1 receptor (GLP1R) is a gut hormone receptor, intricately linked to regulation of blood glucose homeostasis via several mechanisms. It is an established and emergent drug target in metabolic disease. The PET radioligand 68Ga-DO3A-VS-exendin4 (68Ga-exendin4) has the potential to enable longitudinal studies of GLP1R in the human pancreas.

    Methods: 68Ga-exendin4 PET/CT examinations were performed on overweight-to-obese individuals with type 2 diabetes (n = 13) as part of a larger target engagement study (NCT03350191). A scanning protocol was developed to optimize reproducibility (target amount of 0.5 MBq/kg [corresponding to peptide amount of <0.2 µg/kg], blood sampling, and tracer stability assessment). The pancreas and abdominal organs were segmented, and binding was correlated with clinical parameters.

    Results: Uptake of 68Ga-exendin4 in the pancreas, but not in other abdominal tissues, was high but variable between individuals. There was no evidence of self-blocking of GLP1R by the tracer in this protocol, despite the high potency of exendin4. The results showed that a full dynamic scan can be simplified to a short static scan, potentially increasing throughput and reducing patient discomfort. The 68Ga-exendin4 concentration in the pancreas (i.e., GLP1R density) correlated inversely with the age of the individual and tended to correlate positively with body mass index. However, the total GLP1R content in the pancreas did not.

    Conclusion: In summary, we present an optimized and simplified 68Ga-exendin4 scanning protocol to enable reproducible imaging of GLP1R in the pancreas. 68Ga-exendin4 PET may enable quantification of longitudinal changes in pancreatic GLP1R during the development of type 2 diabetes, as well as target engagement studies of novel glucagonlike peptide-1 agonists.

  • 52.
    Eriksson, Olof
    et al.
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Antaros Med AB, Uppsala.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Akad Sjukhuset, Uppsala, Sweden..
    Haack, Torsten
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Bossart, Martin
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Laitinen, Iina
    Sanofi, Global Imaging, Frankfurt, Germany..
    Larsen, Philip J.
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Berglund, Jan Erik
    Clin Trial Consultants AB, Uppsala, Sweden..
    Antoni, Gunnar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Akad Sjukhuset, Uppsala, Sweden..
    Johansson, Lars
    Antaros Med AB, Uppsala, Sweden..
    Pierrou, Stefan
    Antaros Med AB, Uppsala, Sweden..
    Tillner, Joachim
    Sanofi, Translat Med, Frankfurt, Germany..
    Wagner, Michael
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Imaging of the Glucagon Receptor in Subjects with Type 2 Diabetes2021Inngår i: Journal of Nuclear Medicine, ISSN 0161-5505, E-ISSN 1535-5667, Vol. 62, nr 6, s. 833-838Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Despite the importance of the glucagon receptor (GCGR) in disease and in pharmaceutical drug development, there is a lack of specific and sensitive biomarkers of its activation in humans. The PET radioligand Ga-68-DO3A-VS-Tuna-2 (Ga-68-Tuna-2) was developed to yield a noninvasive imaging marker for GCGR target distribution and drug target engagement in humans. Methods: The biodistribution and dosimetry of Ga-68-Tuna-2 was assessed by PET/CT in 13 individuals with type 2 diabetes as part of a clinical study assessing the occupancy of the dual GCGR/glucagon like peptide-1 receptor agonist SAR425899. Binding of Ga-68-Tuna-2 in liver and reference tissues was evaluated and correlated to biometrics (e.g., weight or body mass index) or other biomarkers (e.g., plasma glucagon levels). Results: Ga-68-Tuna-2 binding was seen primarily in the liver, which is in line with the strong expression of GCGR on hepatocytes. The kidneys demonstrated high excretion-related retention, whereas all other tissue demonstrated rapid washout. The SUV55 (min) (SUV during the last 10-min time frame, 50-60 min after administration) uptake endpoint was sensitive to endogenous levels of glucagon. Ga-68-Tuna-2 exhibited a safe dosimetry profile and no adverse events after intravenous administration. Conclusion: Ga-68-Tuna-2 can be used for safe and accurate assessment of the GCGR in human. It may serve as an important tool in understanding the in vivo pharmacology of novel drugs engaging the GCGR.

  • 53.
    Eriksson, Olof
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Selvaraju, Ram K
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Kandeel, Fouad
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Antoni, Gunnar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Eriksson, Barbro
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Endokrin tumörbiologi.
    Sörensen, Jens
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för nuklearmedicin och PET.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Detection of Metastatic Insulinoma by Positron Emission Tomography with [(68)Ga]Exendin-4 -: a case report2014Inngår i: Journal of Clinical Endocrinology and Metabolism, ISSN 0021-972X, E-ISSN 1945-7197, Vol. 99, nr 5, s. 1519-1524Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Context:

    Insulinomas are the most common cause of endogenous hyperinsulinaemic hypoglycaemia in non-diabetic adult patients. They are usually benign and curative surgery is the "gold standard" treatment if they can be localized. Malignant insulinomas are seen in less than 10% and their prognosis is poor. The Glucagon Like Peptide-1 receptor (GLP-1R) is markedly upregulated in insulinomas - especially benign lesions which are difficult to localize with current imaging techniques.

    Objective:

    To assess the possibility of the detection of primary and metastatic insulinoma by PET using [(68)Ga]Ga-DO3A-VS-Cys(40)-Exendin-4 ([(68)Ga]Exendin-4) in a patient with severe hypoglycemia.

    Design:

    Dynamic and static PET/CT examination of a patient using [68Ga]Exendin-4.

    Setting:

    Uppsala University Hospital, Uppsala, Sweden.

    Patients:

    A patient presented with hypoglycemia requiring continuous intravenous glucose infusions. A pancreatic insulinoma was suspected and an exploratory laparotomy was urgently performed. At surgery, a tumor in the pancreatic tail with an adjacent metastasis was found and a distal pancreatic resection (plus splenectomy) and removal of lymph node was performed. Histopathology showed a WHO grade II insulinoma. Postoperatively hypoglycemia persisted but a PET/CT examination using the neuroendocrine marker [(11)C]-5-hydroxy-L-tryptophan was negative.

    Interventions:

    The patient was administered with [(68)Ga]Exendin-4 and examined by dynamic PET over the liver and pancreas.

    Main Outcome Measures:

    N/A

    Results:

    The stable GLP-1 analogue Exendin-4 was labeled with (68)Ga for PET imaging of GLP-1R expressing tumors. The patient was examined by [(68)Ga]Exendin-4-PET/CT which confirmed several small GLP-1R positive lesions in the liver and a lymph node that could not be conclusively identified by other imaging techniques. The results obtained from the [(68)Ga]Exendin-4-PET/CT examination provided the basis for continued systemic treatment.

    Conclusion:

    The results of the [(68)Ga]Exendin-4-PET/CT examination governed the treatment strategy of this particular patient and demonstrated the potential of this technique for future management of patients with this rare, but potentially fatal disease.

  • 54.
    Eriksson, Olof
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för onkologi, radiologi och klinisk immunologi, Enheten för radiologi.
    Wallberg, Andreas
    Syvänen, Stina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för farmaceutisk biovetenskap.
    Josephsson, Raymond
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Klinisk virologi.
    Långström, Bengt
    Uppsala universitet, Teknisk-naturvetenskapliga vetenskapsområdet, Kemiska sektionen, Institutionen för biokemi och organisk kemi.
    Bergström, Mats
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för farmaceutisk biovetenskap.
    A computerized Infusion Pump for control of tissue tracer concentration during Positron Emission Tomography in vivo Pharmacokinetic/Pharmacodynamic measurements2008Inngår i: BMC Medical Physics, E-ISSN 1756-6649, Vol. 8, nr 2Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    BACKGROUND:

    A computer controlled infusion pump (UIPump) for regulation of target tissue concentration of radioactive compounds was developed for use in biological research and tracer development for PET.

    METHODS:

    Based on observed tissue or plasma kinetics after a bolus injection of the tracer an algorithm calculates the infusion needed to obtain a specified target kinetic curve. A computer feeds this infusion scheme into an infusion pump connected to an animal via a venous catheter. The concept was validated using [11C]Flumazenil administrated to Sprague-Dawley rats where the whole brain distribution and kinetic of the tracer was measured over time using a microPET-scanner. The accuracy and precision of the system was assessed by producing steady-state levels of the tracer and by mimicking kinetics after oral administration.

    RESULTS:

    Various kinetic profiles could be generated, including rapid achievement of constant levels, or step-wise increased levels. The resulting tissue curves had low deviation from the target curves according to the specified criteria: AUC (%): 4.2 +/- 2.8, Maximal deviation (%): 13.6 +/- 5.0 and R2: 0.95 +/- 0.02.

    CONCLUSION:

    The UIPump-system is suitable for use in PET-research for assessment of PK/PD properties by simulation of different tracer tissue kinetics in vivo.

  • 55.
    Espes, Daniel
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Transplantation och regenerativ medicin.
    Carlsson, Per-Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Transplantation och regenerativ medicin.
    Selvaraju, Ram Kumar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Rosestedt, Maria
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Cheung, Pierre
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Ahlström, Håkan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi. Antaros Medical AB, Mölndal, Sweden.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Longitudinal Assessment of 11C-5-Hydroxytryptophan Uptake in Pancreas After Debut of Type 1 Diabetes2021Inngår i: Diabetes, ISSN 0012-1797, E-ISSN 1939-327X, Vol. 70, nr 4, s. 966-975Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    The longitudinal alterations of the pancreatic β-cell and islet mass in the progression of type 1 diabetes (T1D) are still poorly understood. The objective of this study was to repeatedly assess the endocrine volume and the morphology of the pancreas for up to 24 months after T1D diagnosis (n = 16), by 11C-5-hydroxytryptophan (11C-5-HTP) positron emission tomography (PET) and MRI. Study participants were examined four times by PET/MRI: at recruitment and then after 6, 12, and 24 months. Clinical examinations and assessment of β-cell function by a mixed-meal tolerance test and fasting blood samples were performed in connection with the imaging examination. Pancreas volume has a tendency to decrease from 50.2 ± 10.3 mL at T1D debut to 42.2 ± 14.6 mL after 24 months (P < 0.098). Pancreas uptake of 11C-5-HTP (e.g., the volume of the endocrine pancreas) did not decrease from T1D diagnosis (0.23 ± 0.10 % of injected dose) to 24-month follow-up, 0.21 ± 0.14% of injected dose, and exhibited low interindividual changes. Pancreas perfusion was unchanged from diagnosis to 24-month follow-up. The pancreas uptake of 11C-5-HTP correlated with the long-term metabolic control as estimated by HbA1c (P < 0.05). Our findings argue against a major destruction of β-cell or islet mass in the 2-year period after diagnosis of T1D.

  • 56.
    Espes, Daniel
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Lau, Joey
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Carlsson, Per-Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper.
    Striated Muscle as Implantation Site for Transplanted Pancreatic Islets2011Inngår i: Journal of Transplantation, ISSN 2090-0007, E-ISSN 2090-0015, Vol. 2011, s. 352043-Artikkel, forskningsoversikt (Fagfellevurdert)
    Abstract [en]

    Islet transplantation is an attractive treatment for selected patients with brittle type 1 diabetes. In the clinical setting, intraportal transplantation predominates. However, due to extensive early islet cell death, the quantity of islets needed to restore glucose homeostasis requires in general a minimum of two donors. Moreover, the deterioration of islet function over time results in few insulin-independent patients after five-year followup. Specific obstacles to the success of islet transplantation include site-specific concerns for the liver such as the instant blood mediated inflammatory reaction, islet lipotoxicity, low oxygen tension, and poor revascularization, impediments that have led to the developing interest for alternative implantation sites over recent years. Within preclinical settings, several alternative sites have now been investigated and proven favorable in various aspects. Muscle is considered a very promising site and has physiologically properties and technical advantages that could make it optimal for islet transplantation.

  • 57.
    Espes, Daniel
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Transplantation och regenerativ medicin.
    Manell, Elin
    Department of Clinical Sciences, Swedish University of Agricultural Sciences, Uppsala, Sweden.
    Rydén, Anneli
    Department of Clinical Sciences, Swedish University of Agricultural Sciences, Uppsala, Sweden.
    Carlbom, Lina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi.
    Weis, Jan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi.
    Jensen-Waern, Marianne
    Department of Clinical Sciences, Swedish University of Agricultural Sciences, Uppsala, Sweden.
    Jansson, Leif
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Theranostics. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Pancreatic perfusion and its response to glucose as measured by simultaneous PET/MRI2019Inngår i: Acta Diabetologica, ISSN 0940-5429, E-ISSN 1432-5233, Vol. 56, nr 10, s. 1113-1120Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    AIMS: Perfusion of the pancreas and the islets of Langerhans is sensitive to physiological stimuli and is dysregulated in metabolic disease. Pancreatic perfusion can be assessed by both positron emission tomography (PET) and magnetic resonance imaging (MRI), but the methods have not been directly compared or benchmarked against the gold-standard microsphere technique.

    METHODS: Pigs (n = 4) were examined by [15O]H2O PET and intravoxel incoherent motion (IVIM) MRI technique simultaneously using a hybrid PET/MRI scanner. The pancreatic perfusion was measured both at basal conditions and after intravenous (IV) administration of up to 0.5 g/kg glucose.

    RESULTS: Pancreatic perfusion increased by 35%, 157%, and 29% after IV 0.5 g/kg glucose compared to during basal conditions, as assessed by [15O]H2O PET, IVIM MRI, and microspheres, respectively. There was a correlation between pancreatic perfusion as assessed by [15O]H2O PET and IVIM MRI (r = 0.81, R2 = 0.65, p < 0.01). The absolute quantification of pancreatic perfusion (ml/min/g) by [15O]H2O PET was within a 15% error of margin of the microsphere technique.

    CONCLUSION: Pancreatic perfusion by [15O]H2O PET was in agreement with the microsphere technique assessment. The IVIM MRI method has the potential to replace [15O]H2O PET if the pancreatic perfusion is sufficiently large, but not when absolute quantitation is required.

    Fulltekst (pdf)
    fulltext
  • 58.
    Espes, Daniel
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper.
    Selvaraju, Ramkumar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Krajcovic, Martin
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Carlsson, Per-Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Turku PET center, Faculty of Natural Sciences and Technology, Åbo Akademi, Turku, Finland.
    Quantification of Beta-Cell Mass in Intramuscular Islet Grafts using Radiolabeled Exendin-42016Inngår i: Transplantation Direct, ISSN 2373-8731, Vol. 2, nr 8, artikkel-id e93Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Background: There is an increasing interest in alternative implantation sites to the liver for islet transplantation. Intramuscular implantation has even been tested clinically. Possibilities to monitor [beta]-cell mass would be of huge importance not only for the understanding of islet engraftment but also for the decision of changing the immunosuppressive regime. We have therefore evaluated the feasibility of quantifying intramuscular [beta]-cell mass using the radiolabeled glucagon like peptide-1 receptor agonist DO3A-VS-Cys40-Exendin-4.

    Methods: One hundred to 400 islets were transplanted to the abdominal muscle of nondiabetic mice. After 3 to 4 weeks, 0.2 to 0.5 MBq [177Lu]DO3A-VS-Cys40-Exendin-4 was administered intravenously. Sixty minutes postinjection abdominal organs and graft bearing muscle were retrieved, and the radioactive uptake measured in a well counter within 10 minutes. The specific uptake in native and transplanted islets was assessed by autoradiography. The total insulin-positive area of the islet grafts was determined by immunohistochemistry.

    Results: Intramuscular islet grafts could easily be visualized by this tracer, and the background uptake was very low. There was a linear correlation between the radioactivity uptake and the number of transplanted islets, both for standardized uptake values and the total radiotracer uptake in each graft (percentage of injected dose). The quantified total insulin area of surviving [beta] cells showed an even stronger correlation to both standardized uptake values (R = 0.96, P = 0.0002) and percentage of injected dose (R = 0.88, P = 0.0095). There was no correlation to estimated [alpha] cell mass.

    Conclusions: [177Lu]DO3A-VS-Cys40-Exendin-4 could be used to quantify [beta]-cell mass after experimental intramuscular islet transplantation. This technique may well be transferred to the clinical setting by exchanging Lutetium-177 radionuclide to a positron emitting Gallium-68.

    Fulltekst (pdf)
    fulltext
  • 59.
    Gotthardt, Martin
    et al.
    Radboud Univ Nijmegen, Med Ctr, Dept Radiol & Nucl Med, POB 9101, NL-6500 HB Nijmegen, Netherlands.
    Eizirik, Decio L.
    Univ Libre Bruxelles, Fac Med, ULB Ctr Diabet Res, Brussels, Belgium.
    Aanstoot, Henk-Jan
    Ctr Pediat & Adolescent Diabet Care & Res, Diabeter, Rotterdam, Netherlands.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Mul, Dick
    Ctr Pediat & Adolescent Diabet Care & Res, Diabeter, Rotterdam, Netherlands.
    Martin, Frank
    JDRF, New York, NY USA.
    Boss, Marti
    Radboud Univ Nijmegen, Med Ctr, Dept Radiol & Nucl Med, POB 9101, NL-6500 HB Nijmegen, Netherlands.
    Jansen, Tom J. P.
    Radboud Univ Nijmegen, Med Ctr, Dept Radiol & Nucl Med, POB 9101, NL-6500 HB Nijmegen, Netherlands.
    van Lith, Sanne A. M.
    Radboud Univ Nijmegen, Med Ctr, Dept Radiol & Nucl Med, POB 9101, NL-6500 HB Nijmegen, Netherlands.
    Buitinga, Mijke
    Univ Leuven, Clin & Expt Endocrinol, Leuven, Belgium.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Theranostics.
    Cnop, Miriam
    Univ Libre Bruxelles, Fac Med, ULB Ctr Diabet Res, Brussels, Belgium;Univ Libre Bruxelles, Erasmus Hosp, Div Endocrinol, Brussels, Belgium.
    Brom, Maarten
    Radboud Univ Nijmegen, Med Ctr, Dept Radiol & Nucl Med, POB 9101, NL-6500 HB Nijmegen, Netherlands.
    Detection and quantification of beta cells by PET imaging: why clinical implementation has never been closer2018Inngår i: Diabetologia, ISSN 0012-186X, E-ISSN 1432-0428, Vol. 61, nr 12, s. 2516-2519Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    In this issue of Diabetologia, Alavi and Werner (10.1007/s00125-018-4676-1) criticise the attempts to use positron emission tomography (PET) for in vivo imaging of pancreatic beta cells, which they consider as futile'. In support of this strong statement, they point out the limitations of PET imaging, which they believe render beta cell mass impossible to estimate using this method. In our view, the Alavi and Werner presentation of the technical limitations of PET imaging does not reflect the current state of the art, which leads them to questionable conclusions towards the feasibility of beta cell imaging using this approach. Here, we put forward arguments in favour of continuing the development of innovative technologies enabling in vivo imaging of pancreatic beta cells and concisely present the current state of the art regarding putative technical limitations of PET imaging. Indeed, far from being a futile' effort, we demonstrate that beta cell imaging is now closer than ever to becoming a long-awaited clinical reality.

  • 60.
    Gustafsson, Sofia
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för farmaceutisk biovetenskap.
    Eriksson, Jonas
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för organisk farmaceutisk kemi.
    Syvänen, Stina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för folkhälso- och vårdvetenskap, Geriatrik.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Hammarlund-Udenaes, Margareta
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för farmaceutisk biovetenskap.
    Antoni, Gunnar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Combined PET and microdialysis for in vivo estimation of drug blood-brain barrier transport and brain unbound concentrations2017Inngår i: NeuroImage, ISSN 1053-8119, E-ISSN 1095-9572, Vol. 155, s. 177-186Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Methods to investigate blood-brain barrier transport and pharmacologically active drug concentrations in the human brain are limited and data translation between species is challenging. Hence, there is a need to further develop the read-out of techniques like positron emission tomography ( PET) for studying neuropharmacokinetics. PET has a high translational applicability from rodents to man and measures total drug concentrations in vivo. The aim of the present study was to investigate the possibility of translating total drug concentrations, acquired through PET, to unbound concentrations, resembling those measured in the interstitial fluid by microdialysis sampling. Simultaneous PET scanning and brain microdialysis sampling were performed in rats throughout a 60 min infusion of [N-methyl-C-11] oxycodone in combination with a therapeutic dose of oxycodone and during a 60 min follow up period after the end of infusion. The oxycodone concentrations acquired with PET were converted into unbound concentrations by compensating for brain tissue binding and brain intracellular distribution, using the unbound volume of distribution in brain (Vu, brain), and were compared to microdialysis measurements of unbound concentrations. A good congruence between the methods was observed throughout the infusion. However, an accumulating divergence in the acquired PET and microdialysis data was apparent and became more pronounced during the elimination phase, most likely due to the passage of radioactive metabolites into the brain. In conclusion, the study showed that PET can be used to translate non-invasively measured total drug concentrations into unbound concentrations as long as the contribution of radiolabelled metabolites is minor or can be compensated for.

  • 61.
    Haylock, Anna-Karin
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Öron-, näs- och halssjukdomar. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi.
    Spiegelberg, Diana
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Mortensen, Anja C.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Selvaraju, Ram K.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Nilvebrant, Johan
    Royal Inst Technol, Sch Biotechnol, Div Prot Technol, Stockholm, Sweden.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Tolmachev, Vladimir
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Nestor, Marika V
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Öron-, näs- och halssjukdomar.
    Evaluation of a novel type of imaging probe based on a recombinant bivalent mini-antibody construct for detection of CD44v6-expressing squamous cell carcinoma2016Inngår i: International journal of oncology, ISSN 1791-2423, Vol. 48, nr 2, s. 461-470Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    We have developed the CD44v6-targeting human bivalent antibody fragment AbD19384, an engineered recombinant human bivalent Fab antibody formed via dimerization of dHLX (synthetic double helix loop helix motif) domains, for potential use in antibody-based molecular imaging of squamous cell carcinoma in the head and neck region. This is a unique construct that has, to the best of our knowledge, never been assessed for molecular imaging in vivo before. The objective of the present study was to evaluate for the first time the in vitro and in vivo binding properties of radio-iodinated AbD19384, and to assess its utility as a targeting agent for molecular imaging of CD44v6-expressing tumors. Antigen specificity and binding properties were assessed in vitro. In vivo specificity and biodistribution of 125I-AbD19384 were next evaluated in tumor-bearing mice using a dual-tumor setup. Finally, AbD19384 was labeled with 124I, and its imaging properties were assessed by small animal PET/CT in tumor bearing mice, and compared with 2-deoxy-2-[18F]fluoro-D-glucose (18F-FDG). In vitro studies demonstrated CD44v6-specific binding with slow off-rate for AbD19384. A favorable biodistribution profile was seen in vivo, with tumor-specific uptake. Small animal PET/CT images of 124I-AbD19384 supported the results through clearly visible high CD44v6-expressing tumors and faintly visible low expressing tumors, with superior imaging properties compared to 18F-FDG. Tumor-to-blood ratios increased with time for the conjugate (assessed up to 72 h p.i.), although 48 h p.i. proved best for imaging. Biodistribution and small-animal PET studies demonstrated that the recombinant Fab-dHLX construct AbD19384 is a promising tracer for imaging of CD44v6 antigen expression in vivo, with the future aim to be used for individualized diagnosis and early detection of squamous cell carcinomas in the head and neck region. Furthermore, this proof-of-concept research established the feasibility of using recombinant Fab-dHLX constructs for in vivo imaging of tumor biomarkers.

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    fulltext
  • 62.
    Hellström-Lindahl, Ewa
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Danielsson, Angelika
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi.
    Pontén, Fredrik
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi.
    Czernichow, Paul
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    GPR44 is a pancreatic protein restricted to the human beta cell2016Inngår i: Acta Diabetologica, ISSN 0940-5429, E-ISSN 1432-5233, Vol. 53, nr 3, s. 413-421Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    AIMS: To address questions regarding onset and progression of types 1 and 2 diabetes (T1D/T2D), surrogate imaging biomarkers for beta cell function and mass are needed. Here, we assess the potential of GPR44 as a surrogate marker for beta cells, in a direct comparison with clinically used biomarker VMAT2.

    METHODS: GPR44 surface availability was assessed by flow cytometry of human beta cells. RNA transcription levels in different pancreas compartments were evaluated. The density of GPR44 receptor in endocrine and exocrine tissues was assessed by the radiolabeled GPR44 ligand [(3)H]AZD 3825. A direct comparison with the established beta cell marker VMAT2 was performed by radiolabeled [(3)H]DTBZ.

    RESULTS: GPR44 was available on the cell surface, and pancreatic RNA levels were restricted to the islets of Langerhans. [(3)H]AZD 3825 had nanomolar affinity for GPR44 in human islets and EndoC-βH1 beta cells, and the specific binding to human beta cells was close to 50 times higher than in exocrine preparations. The endocrine-to-exocrine binding ratio was approximately 10 times higher for [(3)H]AZD 3825 than for [(3)H]DTBZ.

    CONCLUSION: GPR44 is a highly beta cell-specific target, which potentially offers improved imaging contrast between the human beta cell and the exocrine pancreas.

  • 63.
    Hellström-Lindahl, Ewa
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Åberg, Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Ericsson, Cecilia
    AstraZeneca R&D, SE-43150 Molndal, Sweden..
    O'Mahony, Gavin
    AstraZeneca R&D, SE-43150 Molndal, Sweden..
    Johnström, Peter
    Karolinska Inst, Karolinska Univ Hosp, AstraZeneca PET Sci Ctr, Personalised Healthcare & Biomarkers, SE-17176 Stockholm, Sweden..
    Skrtic, Stanko
    AstraZeneca R&D, SE-43150 Molndal, Sweden.;Univ Gothenburg, Sahlgrenska Acad, Inst Med, SE-41345 Gothenburg, Sweden..
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Toward molecular imaging of the free fatty acid receptor 12017Inngår i: Acta Diabetologica, ISSN 0940-5429, E-ISSN 1432-5233, Vol. 54, nr 7, s. 663-668Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Molecular imaging of the free fatty acid receptor 1 (FFAR1) would be a valuable tool for drug development by enabling in vivo target engagement studies in human. It has also been suggested as a putative target for beta cell imaging, but the inherent lipophilicity of most FFAR1 binders produces high off-target binding, which has hampered progress in this area. The aim of this study was to generate a suitable lead compound for further PET labeling. In order to identify a lead compound for future PET labeling for quantitative imaging of FFAR1 in human, we evaluated tritiated small molecule FFAR1 binding probes ([H-3]AZ1, [H-3]AZ2 and [H-3]TAK-875) for their off-target binding, receptor density and affinity in human pancreatic tissue (islets and exocrine) and rodent insulinoma. [H-3]AZ1 showed improved specificity to FFAR1, with decreased off-target binding compared to [H-3]AZ2 and [H-3]TAK-875, while retaining high affinity in the nanomolar range. FFAR1 density in human islets was approximately 50% higher than in exocrine tissue. AZ1 is a suitable lead compound for PET labeling for molecular imaging of FFAR1 in humans, due to high affinity and reduced off-target binding.

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  • 64. Jahan, M.
    et al.
    Johnstrom, P.
    Nag, S.
    Takano, A.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi.
    Halldin, C.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Synthesis and biological evaluation of [C-11]AZ12504948; a novel tracer for imaging of glucokinase in pancreas and liver2015Inngår i: Nuclear Medicine and Biology, ISSN 0969-8051, E-ISSN 1872-9614, Vol. 42, nr 4, s. 387-394Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Introduction: Glucokinase (GK) is potentially a target for imaging of islets of Langerhans. Here we report the radiosynthesis and preclinical evaluation of the GK activator, [C-11]AZ12504948, for in vivo imaging of GK. Methods: [C-11]AZ12504948 was synthesized by O-methylation of the precursor, AZ125555620, using carbon-11 methyl iodide ([C-11]CH3I).Preclinical evaluation was performed by autoradiography (ARC) of human tissues and PET/CT studies in pig and non-human primate. Result: [C-11]AZ12504948 was produced in reproducible good radiochemical yield in 28-30 min. Radiochemical purity of the formulated product was >98% for up to 2 h with specific radioactivities 855 +/- 209 GBq/mu mol (n = 8). The preclinical evaluation showed some specificity for GK in liver, but not in pancreas. Conclusion:[C-11]AZ12504948 images GK in liver, but the low specificity impedes the visualization of GK in pancreas. Improved target specificity is required for further progress using PET probes based on this class of GK activators.

  • 65. Jahan, Mahabuba
    et al.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Johnström, Peter
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Sundin, Anders
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Halldin, Christer
    Decreased defluorination using the novel beta-cell imaging agent [18F]FE-DTBZ-d4 in pigs examined by PET2011Inngår i: EJNMMI Research, E-ISSN 2191-219X, Vol. 1, nr 1, s. 33-Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Background

    Fluorine-18 dihydrotetrabenazine [DTBZ] analogues, which selectively target the vesicular monoamine transporter 2 [VMAT2], have been extensively studied for in vivo quantification of beta cell mass by positron-emission tomography [PET]. This study describes a novel deuterated radioligand [18F]fluoroethyl [FE]-DTBZ-d4, aimed to increase the stability against in vivo defluorination previously observed for [18F]FE-DTBZ.

    Methods

    [18F]FE-DTBZ-d4 was synthesized by alkylation of 9-O-desmethyl-(+)-DTBZ precursor with deuterated [18F]FE bromide ([18F]FCD2CD2Br). Radioligand binding potential [BP] was assessed by an in vitro saturation homogenate binding assay using human endocrine and exocrine pancreatic tissues. In vivo pharmacokinetics and pharmacodynamics [PK/PD] was studied in a porcine model by PET/computed tomography, and the rate of defluorination was quantified by compartmental modeling.

    Results

    [18F]FE-DTBZ-d4 was produced in reproducible good radiochemical yield in 100 ± 20 min. Radiochemical purity of the formulated product was > 98% for up to 5 h with specific radioactivities that ranged from 192 to 529 GBq/μmol at the end of the synthesis. The in vitro BP for VMAT2 in the islet tissue was 27.0 ± 8.8, and for the exocrine tissue, 1.7 ± 1.0. The rate of in vivo defluorination was decreased significantly (kdefluorination = 0.0016 ± 0.0007 min-1) compared to the non-deuterated analogue (kdefluorination = 0.012 ± 0.002 min-1), resulting in a six fold increase in half-life stability.

    Conclusions

    [18F]FE-DTBZ-d4 has similar PK and PD properties for VMAT2 imaging as its non-deuterated analogue [18F]FE-DTBZ in addition to gaining significantly increased stability against defluorination. [18F]FE-DTBZ-d4 is a prime candidate for future preclinical and clinical studies on focal clusters of beta cells, such as in intramuscular islet grafts.

  • 66. Jahan, Mahabuba
    et al.
    Johnström, Peter
    Selvaraju, Ramkumar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Svedberg, Marie
    Winzell, Maria Sörhede
    Bernström, Jenny
    Kingston, Lee
    Schou, Magnus
    Jia, Zhisheng
    Skrtic, Stanko
    Johansson, Lars
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Farde, Lars
    Halldin, Christer
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Theranostics.
    The development of a GPR44 targeting radioligand [11C]AZ12204657 for in vivo assessment of beta cell mass.2018Inngår i: EJNMMI Research, E-ISSN 2191-219X, Vol. 8, artikkel-id 113Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    BACKGROUND: The G-protein-coupled receptor 44 (GPR44) is a beta cell-restricted target that may serve as a marker for beta cell mass (BCM) given the development of a suitable PET ligand.

    METHODS: The binding characteristics of the selected candidate, AZ12204657, at human GPR44 were determined using in vitro ligand binding assays. AZ12204657 was radiolabeled using 11C- or 3H-labeled methyl iodide ([11C/3H]CH3I) in one step, and the conversion of [11C/3H]CH3I to the radiolabeled product [11C/3H]AZ12204657 was quantitative. The specificity of radioligand binding to GPR44 and the selectivity for beta cells were evaluated by in vitro binding studies on pancreatic sections from human and non-human primates as well as on homogenates from endocrine and exocrine pancreatic compartments.

    RESULTS: The radiochemical purity of the resulting radioligand [11C]AZ12204657 was > 98%, with high molar activity (MA), 1351 ± 575 GBq/μmol (n = 18). The radiochemical purity of [3H]AZ12204657 was > 99% with MA of 2 GBq/μmol. Pancreatic binding of [11C/3H]AZ12204657 was co-localized with insulin-positive islets of Langerhans in non-diabetic individuals and individuals with type 2 diabetes (T2D). The binding of [11C]AZ12204657 to GPR44 was > 10 times higher in islet homogenates compared to exocrine homogenates. In human islets of Langerhans GPR44 was co-expressed with insulin, but not glucagon as assessed by co-staining and confocal microscopy.

    CONCLUSION: We radiolabeled [11C]AZ12204657, a potential PET radioligand for the beta cell-restricted protein GPR44. In vitro evaluation demonstrated that [3H]AZ12204657 and [11C]AZ12204657 selectively target pancreatic beta cells. [11C]AZ12204657 has promising properties as a marker for human BCM.

    Fulltekst (pdf)
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  • 67.
    Jansen, Theodorus J. P.
    et al.
    Radboud Univ Nijmegen, Dept Med Imaging, Med Ctr, Nijmegen, Netherlands..
    Buitinga, Mijke
    Maastricht Univ, Dept Nutr & Movement Sci, Maastricht, Netherlands.;Maastricht Univ, Dept Radiol & Nucl Med, Med Ctr, Maastricht, Netherlands..
    Boss, Marti
    Radboud Univ Nijmegen, Dept Med Imaging, Med Ctr, Nijmegen, Netherlands..
    Nijhoff, Michiel F.
    Leiden Univ, Internal Med, Med Ctr, Leiden, Netherlands..
    Brom, Maarten
    Radboud Univ Nijmegen, Dept Med Imaging, Med Ctr, Nijmegen, Netherlands..
    de Galan, Bastiaan E.
    Radboud Univ Nijmegen, Internal Med, Med Ctr, Nijmegen, Netherlands.;Maastricht Univ, Internal Med, Med Ctr, Maastricht, Netherlands.;Maxima Med Ctr, Internal Med, Veldhoven, Netherlands..
    van der Graaf, Marinette
    Radboud Univ Nijmegen, Dept Med Imaging, Med Ctr, Nijmegen, Netherlands..
    van Koeverden, Sebastiaan
    Radboud Univ Nijmegen, Dept Med Imaging, Med Ctr, Nijmegen, Netherlands..
    Vantyghem, Marie-Christine
    CHU Lille, Endocrinol, Lille, France.;Translat Res Diabet, Lille, France..
    Beron, Amandine
    CHU Lille, Nucl Med, Lille, France..
    Pattou, Francois
    Translat Res Diabet, Lille, France..
    Engelse, Marten A.
    Leiden Univ, Internal Med, Med Ctr, Leiden, Netherlands..
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    de Koning, Eelco J. P.
    Leiden Univ, Internal Med, Med Ctr, Leiden, Netherlands..
    Gotthardt, Martin
    Radboud Univ Nijmegen, Dept Med Imaging, Med Ctr, Nijmegen, Netherlands..
    Monitoring beta-Cell Survival After Intrahepatic Islet Transplantation Using Dynamic Exendin PET Imaging: A Proof-of-Concept Study in Individuals With Type 1 Diabetes2023Inngår i: Diabetes, ISSN 0012-1797, E-ISSN 1939-327X, Vol. 72, nr 7, s. 898-907Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Intrahepatic transplantation of islets of Langerhans (ITx) is a treatment option for individuals with complicated type 1 diabetes and profoundly unstable glycemic control, but its therapeutic success is hampered by deterioration of graft function over time. To improve ITx strategies, technologies to noninvasively monitor the fate and survival of transplanted islets over time are of great potential value. We used [Ga-68]Ga-NODAGA-exendin-4 (Ga-68-exendin) positron emission tomography (PET)/computed tomography (CT) imaging to demonstrate the feasibility of quantifying b-cellmass in intrahepatic islet grafts in 13 individuals with type 1 diabetes, nine after ITx with functional islet grafts and four control patients not treated with ITx. beta-Cell function was measured by mixed-meal tolerance test. With dynamic Ga-68-exendin PET/CT images, we determined tracer accumulation in hepatic hotspots, and intrahepatic fat was assessed using MRI and spectroscopy. Quantification of hepatic hotspots showed a significantly higher uptake of Ga-68-exendin in the ITx group compared with the control group (median 0.55 [interquartile range 0.51-0.63] vs. 0.43 [0.42-0.45]). GLP-1 receptor expression was found in transplanted islets by immunohistochemistry. Intrahepatic fat was not detected in a majority of the individuals. Our study provides the first clinical evidence that radiolabeled exendin imaging can be used to monitor viable transplanted islets after intraportal ITx.

  • 68.
    Kang, Nam-Young
    et al.
    Agcy Sci Technol & Res, Lab Bioimaging Probe Dev, Singapore Bioimaging Consortium, 11 Biopolis Way,02-02 Helios, Singapore 138667, Singapore;DGMIF, New Drug Dev Ctr, 80 Chembok Ro,1115-1 Dongnae Dong, Daegu City 41061, South Korea.
    Soetedjo, Andreas Alvin Purnomo
    Inst Mol & Cell Biol, Stem Cells & Diabet Lab, Singapore 138673, Singapore.
    Amirruddin, Nur Shabrina
    Inst Mol & Cell Biol, Stem Cells & Diabet Lab, Singapore 138673, Singapore;Natl Univ Singapore, Dept Med, Yong Loo Lin Sch Med, Singapore 119228, Singapore.
    Chang, Young-Tae
    Agcy Sci Technol & Res, Lab Bioimaging Probe Dev, Singapore Bioimaging Consortium, 11 Biopolis Way,02-02 Helios, Singapore 138667, Singapore;Pohang Univ Sci & Technol POSTECH, Dept Chem, Pohang 37673, Gyeongbuk, South Korea;Inst for Basic Sci Korea, Ctr Self Assembly & Complex, 77 Hyogok Dong, Pohang 37673, South Korea.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Teo, Adrian Kee Keong
    Inst Mol & Cell Biol, Stem Cells & Diabet Lab, Singapore 138673, Singapore;Natl Univ Singapore, Dept Med, Yong Loo Lin Sch Med, Singapore 119228, Singapore;Natl Univ Singapore, Dept Biochem, Yong Loo Lin Sch Med, Singapore 117596, Singapore;Nanyang Technol Univ, Sch Biol Sci, Singapore 637551, Singapore.
    Tools for Bioimaging Pancreatic beta Cells in Diabetes2019Inngår i: Trends in Molecular Medicine, ISSN 1471-4914, E-ISSN 1471-499X, Vol. 25, nr 8, s. 708-722Artikkel, forskningsoversikt (Fagfellevurdert)
    Abstract [en]

    When diabetes is diagnosed, the majority of insulin-secreting pancreatic beta cells are already dysfunctional or destroyed. This beta cell dysfunction/destruction usually takes place over many years, making timely detection and clinical intervention difficult. For this reason, there is immense interest in developing tools to bioimage beta cell mass and/or function noninvasively to facilitate early diagnosis of diabetes as well as to assist the development of novel antidiabetic therapies. Recent years have brought significant progress in beta cell imaging that is now inching towards clinical applicability. We explore here the need to bioimage human beta cells noninvasively in various types of diabetes, and we discuss current and emerging tools for bioimaging beta cells. Further developments in this field are expected to facilitate beta cell imaging in diabetes.

  • 69.
    Karlsson, Filip
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Antonodimitrakis, Pantelis Clewemar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Endokrin tumörbiologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Systematic screening of imaging biomarkers for the Islets of Langerhans, among clinically available positron emission tomography tracers2015Inngår i: Nuclear Medicine and Biology, ISSN 0969-8051, E-ISSN 1872-9614, Vol. 42, nr 10, s. 762-769Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Introduction: Functional imaging could be utilized for visualizing pancreatic islets of Langerhans. Therefore, we present a stepwise algorithm for screening of clinically available positron emission tomography (PET) tracers for their use in imaging of the neuroendocrine pancreas in the context of diabetes. Methods: A stepwise procedure was developed for screening potential islet imaging agents. Suitable PET-tracer candidates were identified by their molecular mechanism of targeting. Clinical abdominal examinations were retrospectively analyzed for pancreatic uptake and retention. The target protein localization in the pancreas was assessed in silico by -omics approaches and the in vitro by binding assays to human pancreatic tissue. Results: Six putative candidates were identified and screened by using the stepwise procedure. Among the tested PET tracers, only [C-11]5-Hydroxy-tryptophan passed all steps. The remaining identified candidates were falsified as candidates and discarded following in silico and in vitro screening. Conclusions: Of the six clinically available PET tracers identified, [C-11]5-HTP was found to be a promising candidate for beta cell imaging, based on intensity of in vivo pancreatic uptake in humans, and islet specificity as assessed on human pancreatic cell preparations. The flow scheme described herein constitutes a methodology for evaluating putative islet imaging biomarkers among clinically available PET tracers.

  • 70.
    Khalil, Amina
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Hakhverdyan, Sona
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Cheung, Pierre
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Bossart, Martin
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany..
    Wagner, Michael
    Sanofi, Integrated Drug Discovery, R&D Res Platform, Frankfurt, Germany.;Dewpoint Therapeut, Frankfurt, Germany..
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Antaros Med AB, Mölndal, Sweden.;Antaros Tracer AB, Mölndal, Sweden.
    Velikyan, Irina
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi. Uppsala Univ Hosp, PET Ctr, Ctr Med Imaging, Uppsala, Sweden..
    Introduction of a fatty acid chain modification to prolong circulatory half-life of a radioligand towards glucose-dependent insulinotropic polypeptide receptor2024Inngår i: Nuclear Medicine and Biology, ISSN 0969-8051, E-ISSN 1872-9614, Vol. 128, artikkel-id 108876Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Background: The beneficial role of glucose-dependent insulinotropic polypeptide receptor (GIPR) in weight control and maintaining glucose levels has led to the development of several multi-agonistic peptide drug candidates, targeting GIPR and glucagon like peptide 1 receptor (GLP1R) and/or the glucagon receptor (GCGR). The in vivo quantification of target occupancy by these drugs would accelerate the development of new drug candidates. The aim of this study was to evaluate a novel peptide (GIP1234), based on previously reported ligand DOTA-GIP-C803, modified with a fatty acid moiety to prolong its blood circulation. It would allow higher target tissue exposure and consequently improved peptide uptake as well as in vivo PET imaging and quantification of GIPR occupancy by novel drugs of interest. Method: A 40 amino acid residue peptide (GIP1234) was synthesized based on DOTA-GIP-C803, in turn based on the sequences of endogenous GIP and Exendin-4 with specific amino acid modifications to obtain GIPR selectivity. A palmitoyl fatty acid chain was furthermore added at Lys14 via a glutamic acid linker to prolong its blood circulation time by the interaction with albumin. GIP1234 was conjugated with a DOTA chelator at the C -terminal cysteine residue to achieve 68Ga radiolabeling. The resulting PET probe, [68Ga]Ga-DOTA-GIP1234 was evaluated for receptor binding specificity and selectivity using HEK293 cells transfected with human GIPR, GLP1R, or GCGR. Blocking experiments with tirzepatide (2 mu M) were conducted using huGIPR HEK293 cells to investigate binding specificity. Ex vivo and in vivo organ distribution of [68Ga]Ga-DOTA-GIP1234 was studied in rats and a pig in comparison to [68Ga]Ga-DOTA-C803-GIP. Binding of [68Ga]Ga-DOTA-GIP1234 to albumin was assessed in situ using polyacrylamide gel electrophoresis (PAGE). The stability was tested in formulation buffer and rat blood plasma. Results: [68Ga]Ga-DOTA-GIP1234 was synthesized with non-decay corrected radiochemical yield of 88 +/- 3.7 % and radiochemical purity of 97.8 +/- 0.8 %. The molar activity for the radiotracer was 8.1 +/- 1.1 MBq/nmol. [68Ga]Ga-DOTA-GIP1234 was stable and maintained affinity to huGIPR HEK293 cells (dissociation constant (Kd) = 40 +/- 12.5 nM). The binding of [68Ga]Ga-DOTA-GIP1234 to huGCGR and huGLP1R cells was insignificant. Preincubation of huGIPR HEK293 cell sections with tirzepatide resulted in the decrease of [68Ga]Ga-DOTA-GIP1234 binding by close to 90 %. [68Ga]Ga-DOTA-GIP1234 displayed slow blood clearance in pigs with SUV = 3.5 after 60 min. Blood retention of the tracer in rat was 2-fold higher than that of [68Ga]Ga-DOTA-C803-GIP. [68Ga]Ga- DOTA-GIP1234 also demonstrated strong liver uptake in both pig and rat combined with decreased renal excretion. The concentration dependent binding of [68Ga]Ga-DOTA-GIP1234 to albumin was confirmed in situ by PAGE. Conclusion: [68Ga]Ga-DOTA-GIP1234 demonstrated nanomolar affinity and selectivity for huGIPR in vitro. Addition of a fatty acid moiety prolonged blood circulation time and tissue exposure in both rat and pig in vivo. However, the liver uptake was also increased which may make PET imaging of abdominal tissues such as pancreas challenging. The investigation of the influence of fatty acid moiety on the biological performance of the peptide ligand paved the way for further rational design of GIPR ligand analogues with improved characteristics.

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  • 71.
    Koffert, Jukka P.
    et al.
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland.;Southwest Finland Hosp Dist, Turunmaa Hosp, Dept Gastroenterol, Turku, Finland..
    Mikkola, Kirsi
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland..
    Virtanen, Kirsi A.
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland..
    Andersson, Anna-Maria D.
    Lund Univ, Dept Clin Sci Malmo, Diabet Ctr, Malmo, Sweden..
    Faxius, Linda
    Lund Univ, Dept Clin Sci Malmo, Diabet Ctr, Malmo, Sweden..
    Hallsten, Kirsti
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland..
    Heglind, Mikael
    Univ Gothenburg, Sahlgrenska Acad, Inst Biomed, Dept Clin & Med Genet, SE-40530 Gothenburg, Sweden..
    Guiducci, Letizia
    CNR, Inst Clin Physiol, Pisa, Italy..
    Pham, Tam
    Silvola, Johanna M. U.
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland..
    Virta, Jenni
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland..
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland.;Abo Akad Univ, Dept Biosci, Turku, Finland..
    Kauhanen, Saila P.
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland.;Turku Univ Hosp, Div Digest Surg & Urol, Turku, Finland..
    Saraste, Antti
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland.;Turku Univ Hosp, Heart Ctr, Turku, Finland..
    Enerback, Sven
    Univ Gothenburg, Sahlgrenska Acad, Inst Biomed, Dept Clin & Med Genet, SE-40530 Gothenburg, Sweden..
    Iozzo, Patricia
    CNR, Inst Clin Physiol, Pisa, Italy..
    Parkkola, Riitta
    Turku Univ, Dept Radiol, Turku, Finland.;Turku Univ Hosp, Dept Radiol, Turku, Finland..
    Gomez, Maria F.
    Lund Univ, Dept Clin Sci Malmo, Diabet Ctr, Malmo, Sweden..
    Nuutila, Pirjo
    Univ Turku, Turku PET Ctr, PL52, FIN-20520 Turku, Finland.;Turku Univ Hosp, Dept Endocrinol, Turku, Finland..
    Metformin treatment significantly enhances intestinal glucose uptake in patients with type 2 diabetes: Results from a randomized clinical trial2017Inngår i: Diabetes Research and Clinical Practice, ISSN 0168-8227, E-ISSN 1872-8227, Vol. 131, s. 208-216Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Aims: Metformin therapy is associated with diffuse intestinal F-18-fluoro-deoxyglucose (FDG) accumulation in clinical diagnostics using routine FDG-PET imaging. We aimed to study whether metformin induced glucose uptake in intestine is associated with the improved glycaemic control in patients with type 2 diabetes. Therefore, we compared the effects of metformin and rosiglitazone on intestinal glucose metabolism in patients with type 2 diabetes in a randomized placebo controlled clinical trial, and further, to understand the underlying mechanism, evaluated the effect of metformin in rats.

    Methods: Forty-one patients with newly diagnosed type 2 diabetes were randomized to metformin (1 g, b.i.d), rosiglitazone (4 mg, b.i.d), or placebo in a 26-week double-blind trial. Tissue specific intestinal glucose uptake was measured before and after the treatment period using FDG-PET during euglycemic hyperinsulinemia. In addition, rats were treated with metformin or vehicle for 12 weeks, and intestinal FDG uptake was measured in vivo and with autoradiography.

    Results: Glucose uptake increased 2-fold in the small intestine and 3-fold in the colon for the metformin group and associated with improved glycemic control. Rosiglitazone increased only slightly intestinal glucose uptake. In rodents, metformin treatment enhanced intestinal FDG retention (P = 0.002), which was localized in the mucosal enterocytes of the small intestine.

    Conclusions: Metformin treatment significantly enhances intestinal glucose uptake from the circulation of patients with type 2 diabetes. This intestine-specific effect is associated with improved glycemic control and localized to mucosal layer. These human findings demonstrate directs effect of metformin on intestinal metabolism and elucidate the actions of metformin.

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  • 72.
    Lahesmaa, M.
    et al.
    Univ Turku, Turku PET Ctr, Turku, Finland.;Turku Univ Hosp, Turku PET Ctr, Turku, Finland..
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Univ Turku, Turku PET Ctr, Turku, Finland..
    Oikonen, V.
    Univ Turku, Turku PET Ctr, Turku, Finland..
    Bucci, M.
    Univ Turku, Turku PET Ctr, Turku, Finland..
    Hirvonen, J.
    Univ Turku, Turku PET Ctr, Turku, Finland.;Univ Turku, Dept Radiol, Turku, Finland..
    Lahdenpohja, S.
    Univ Turku, Turku PET Ctr, Turku, Finland..
    Koskensalo, K.
    Univ Turku, Turku PET Ctr, Turku, Finland..
    Haaparanta-Solin, M.
    Univ Turku, Turku PET Ctr, Turku, Finland..
    Virtanen, K. A.
    Univ Turku, Turku PET Ctr, Turku, Finland.;Turku Univ Hosp, Turku PET Ctr, Turku, Finland..
    Nuutila, P.
    Univ Turku, Turku PET Ctr, Turku, Finland.;Turku Univ Hosp, Dept Endocrinol, Turku, Finland..
    Cannabinoid CB1 receptors in human brown adipose tissue during cold exposure2016Inngår i: Diabetologia, ISSN 0012-186X, E-ISSN 1432-0428, Vol. 59, s. S50-S50Artikkel i tidsskrift (Fagfellevurdert)
  • 73.
    Lahesmaa, Minna
    et al.
    Univ Turku, Turku PET Ctr, Turku, Finland;Turku Univ Hosp, Turku PET Ctr, Turku, Finland.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Theranostics. Abo Akad Univ, Turku PET Ctr, Turku, Finland.
    Gnad, Thorsten
    Univ Bonn, Inst Pharmacol & Toxicol, Bonn, Germany.
    Oikonen, Vesa
    Univ Turku, Turku PET Ctr, Turku, Finland.
    Bucci, Marco
    Univ Turku, Turku PET Ctr, Turku, Finland.
    Hirvonen, Jussi
    Univ Turku, Turku PET Ctr, Turku, Finland;Univ Turku, Dept Radiol, Turku, Finland.
    Koskensalo, Kalle
    Univ Turku, Turku PET Ctr, Turku, Finland;Turku Univ Hosp, Turku PET Ctr, Turku, Finland.
    Teuho, Jarmo
    Turku Univ Hosp, Turku PET Ctr, Turku, Finland.
    Niemi, Tarja
    Turku Univ Hosp, Dept Plast & Gen Surg, Turku, Finland.
    Taittonen, Markku
    Turku Univ Hosp, Dept Anesthesiol, Turku, Finland.
    Lahdenpohja, Salla
    Univ Turku, Turku PET Ctr, Turku, Finland.
    Din, Mueez U.
    Univ Turku, Turku PET Ctr, Turku, Finland.
    Haaparanta-Solin, Merja
    Univ Turku, Turku PET Ctr, Turku, Finland;Univ Turku, Med Res Labs, Turku, Finland.
    Pfeifer, Alexander
    Univ Bonn, Inst Pharmacol & Toxicol, Bonn, Germany.
    Virtanen, Kirsi A.
    Univ Turku, Turku PET Ctr, Turku, Finland;Turku Univ Hosp, Turku PET Ctr, Turku, Finland.
    Nuutila, Pirjo
    Univ Turku, Turku PET Ctr, Turku, Finland;Turku Univ Hosp, Dept Endocrinol, Turku, Finland.
    Cannabinoid Type 1 Receptors Are Upregulated During Acute Activation of Brown Adipose Tissue2018Inngår i: Diabetes, ISSN 0012-1797, E-ISSN 1939-327X, Vol. 67, nr 7, s. 1226-1236Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Activating brown adipose tissue (BAT) could provide a potential approach for the treatment of obesity and metabolic disease in humans. Obesity is associated with upregulation of the endocannabinoid system, and blocking the cannabinoid type 1 receptor (CB1R) has been shown to cause weight loss and to decrease cardiometabolic risk factors. These effects may be mediated partly via increased BAT metabolism, since there is evidence that CB1R antagonism activates BAT in rodents. To investigate the significance of CB1R in BAT function, we quantified the density of CB1R in human and rodent BAT using the positron emission tomography radioligand [F-18]FMPEP-d(2) and measured BAT activation in parallel with the glucose analog [F-18]fluorodeoxyglucose. Activation by cold exposure markedly increased CB1R density and glucose uptake in the BAT of lean men. Similarly, 3-receptor agonism increased CB1R density in the BAT of rats. In contrast, overweight men with reduced BAT activity exhibited decreased CB1R in BAT, reflecting impaired endocannabinoid regulation. Image-guided biopsies confirmed CB1R mRNA expression in human BAT. Furthermore, CB1R blockade increased glucose uptake and lipolysis of brown adipocytes. Our results highlight that CB1Rs are significant for human BAT activity, and the CB1Rs provide a novel therapeutic target for BAT activation in humans.

  • 74.
    Lechi, Francesco
    et al.
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Eriksson, Jonas
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala Univ Hosp, PET Ctr, Uppsala, Sweden..
    Odell, Luke R.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Wegrzyniak, Olivia
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Lofblom, John
    KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Stockholm, Sweden..
    Frejd, Fredrik
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Cancerprecisionsmedicin. Affibody AB, Solna, Sweden..
    Zhang, Bo
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Optimized method for fluorine-18 radiolabeling of Affibody molecules using RESCA2024Inngår i: EJNMMI Radiopharmacy and Chemistry, E-ISSN 2365-421X, Vol. 9, nr 1, artikkel-id 73Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Background: In recent years, the interest in Al[18F]F as a labeling agent for Positron Emission Tomography (PET) radiotracers has risen, as it allows for fast and efficient fluorine-18 labeling by harnessing chelation chemistry. The introduction of Restrained Complexing Agent (RESCA) as a chelator has also shown that chelator-based radiolabeling reactions can be performed in mild conditions, making the radiolabeling process attractively more facile than most conventional radiofluorination methods. The aim of the study was to establish optimized conditions for Al[18F]F labeling of Affibody molecules using RESCA as a complexing agent, using Z09591 and Z0185, two Affibody proteins targeting PDGFR beta and TNF alpha, respectively, as model compounds.

    Results: The Al[18F]F labeling of RESCA-conjugated Z09591 was tested at different temperatures (rt to 60 degrees C) and with varying reaction times (12 to 60 min), and optimal conditions were then implemented on RESCA-Z0185. The optimized synthesis method was: 1.5-2.5 GBq of cyclotron produced fluorine-18 were trapped on a QMA cartridge and eluted with saline solution to react with 12 nmol of AlCl3 and form Al[18F]F. The respective RESCA-conjugated Affibody molecule (14 nmol) in NaOAc solution was added to the Al[18F]F solution and left to react at 60 degrees C for 12 min. The mixture was purified on a NAP5 size exclusion column and then analyzed by HPLC. The entire process took approximately 35 min, was highly reproducible, indicating the efficiency and reliability of the method. The labeled compounds demonstrated retained biological function for their respective targets after purification.

    Conclusions: We present a general and optimized method for Al[18F]F labeling of RESCA-conjugated Affibody molecules, which can be widely applied to this class of peptide-based imaging agents. Moreover, radiochemical yields were improved when the labeling was conducted at 37 degrees C or above. In vitro and in vivo assessment of the respective tracers was promising, showing retained binding capacity as well as moderate defluorination, which is usually regarded as a potential downside for RESCA-conjugated tracers.

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  • 75.
    Liggieri, Francesco
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet. Univ Genoa, Dipartimento Sci Chirurg & Diagnost Integrate, Genoa, Italy.
    Chiodaroli, Elena
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet. San Paolo Univ Hosp, ASST Santi Paolo & Carlo, Dept Anesthesia & Intens Care, Milan, Italy.
    Pellegrini, Mariangela
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet. Uppsala Univ Hosp, Dept Anesthesia & Intens Care Med, Uppsala, Sweden.
    Puuvuori, Emmi
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Sigfridsson, Jonathan
    Uppsala Univ Hosp, PET Ctr, Ctr Med Imaging, Uppsala, Sweden.
    Velikyan, Irina
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Chiumello, Davide
    San Paolo Univ Hosp, ASST Santi Paolo & Carlo, Dept Anesthesia & Intens Care, Milan, Italy.;Univ Milan, Dept Hlth Sci, Milan, Italy.;Univ Milan, Coordinated Res Ctr Resp Failure, Milan, Italy..
    Ball, Lorenzo
    Univ Genoa, Dipartimento Sci Chirurg & Diagnost Integrate, Genoa, Italy..
    Pelosi, Paolo
    Univ Genoa, Dipartimento Sci Chirurg & Diagnost Integrate, Genoa, Italy..
    Stramaglia, Sebastiano
    Univ Bari Aldo Moro, Natl Inst Nucl Phys, Dept Phys, Bari, Italy..
    Antoni, Gunnar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala Univ Hosp, PET Ctr, Ctr Med Imaging, Uppsala, Sweden.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Perchiazzi, Gaetano
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet. Uppsala Univ Hosp, Dept Anesthesia & Intens Care Med, Uppsala, Sweden.
    Regional distribution of mechanical strain and macrophage-associated lung inflammation after ventilator-induced lung injury: an experimental study2024Inngår i: Intensive Care Medicine Experimental, E-ISSN 2197-425X, Vol. 12, nr 1, artikkel-id 77Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Background

    Alveolar macrophages activation to the pro-inflammatory phenotype M1 is pivotal in the pathophysiology of Ventilator-Induced Lung Injury (VILI). Increased lung strain is a known determinant of VILI, but a direct correspondence between regional lung strain and macrophagic activation remains unestablished. [68Ga]Ga-DOTA-TATE is a Positron Emission Tomography (PET) radiopharmaceutical with a high affinity for somatostatin receptor subtype 2 (SSTR2), which is overexpressed by pro-inflammatory-activated macrophages. Aim of the study was to determine, in a porcine model of VILI, whether mechanical strain correlates topographically with distribution of activated macrophages detected by [68Ga]Ga-DOTA-TATE uptake.

    Methods

    Seven anesthetized pigs underwent VILI, while three served as control. Lung CT scans were acquired at incremental tidal volumes, simultaneously recording lung mechanics. [68Ga]Ga-DOTA-TATE was administered, followed by dynamic PET scans. Custom MatLab scripts generated voxel-by-voxel gas volume and strain maps from CT slices at para-diaphragmatic (Para-D) and mid-thoracic (Mid-T) levels. Analysis of regional Voxel-associated Normal Strain (VoStrain) and [68Ga]Ga-DOTA-TATE uptake was performed and a measure of the statistical correlation between these two variables was quantified using the linear mutual information (LMI) method.

    Results

    Compared to controls, the VILI group exhibited statistically significant higher VoStrain and Standardized Uptake Value Ratios (SUVR) both at Para-D and Mid-T levels. Both VoStrain and SUVR increased along the gravitational axis with an increment described by statistically different regression lines between VILI and healthy controls and reaching the peak in the dependent regions of the lung (for strain in VILI vs. control was at Para-D: 760 ± 210 vs. 449 ± 106; at Mid-T level 497 ± 373 vs. 193 ± 160; for SUVR, in VILI vs. control was at Para-D: 2.2 ± 1.3 vs. 1.3 ± 0.1; at Mid-T level 1.3 ± 1.0 vs. 0.6 ± 0.03). LMI in both Para-D and Mid-T was statistically significantly higher in VILI than in controls.

    Conclusions

    In this porcine model of VILI, we found a topographical correlation between lung strain and [68Ga]Ga-DOTA-TATE uptake at voxel level, suggesting that mechanical alteration and specific activation of inflammatory cells are strongly linked in VILI. This study represents the first voxel-by-voxel examination of this relationship in a multi-modal imaging analysis.

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  • 76.
    Lubberink, Mark
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    [11C]5-Hydroxy-tryptophan model for quantitative assessment of in vivo serotonin biosynthesis, retention and degradation in the endocrine pancreas2020Inngår i: American Journal of Nuclear Medicine and Molecular Imaging, ISSN 2160-8407, Vol. 10, nr 5, s. 226-234Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    [11C]5-Hydroxy-tryptophan ([11C]5-HTP) is a Positron Emission Tomography marker for serotonergic biosynthesis and degradation, with use in imaging of neuroendocrine tumors and recently also the endocrine pancreas in diabetes. In order to further develop [11C]5-HTP as a quantitative in vivo tool for understanding the mechanisms of serotonin signaling in human pancreas, we aimed to develop a kinetic modeling approach sensitive for changes in serotonin biosynthesis, retention and degradation. Cynomolgus monkeys were examined by [11C]5-HTP PET/CT, either at baseline (n=9) or following intravenous pretreatment with 3 mg/kg carbidopa (Dopa Decarboxylase inhibitor, n=3) or 2 mg/kg clorgyline (Monoamine Oxidase-A inhibitor, n=5). The dynamic tissue uptake was analysed by a 2-tissue compartment model including an efflux mechanism from the second tissue compartment (2TC kloss), which theoretically reproduces the known processing of 5-HTP in neuroendocrine cells. The 2TC kloss model could accurately describe all three modes of tissue kinetics depending on the pretreatment regiment. Rate constant k3 (corresponding to DDC activity) and the macro-parameter Flux (Ki) was decreased (P<0.05) by carbidopa pretreatment, while k2 (corresponding to cellular washout of intact [11C]5-HTP) was increased (P<0.05). The efflux parameter kloss (corresponding to MAO-A activity) was decreased (P<0.05) by pretreatment of clorgyline, while the macro-parameter Flux/Efflux ratio (Ki/kloss) was increased (P<0.0001). We present a compartment model analysis method that can quantitatively assess in vivo pharmacological interactions with several of the key enzymatic steps of the serotonergic biosynthesis in pancreas.

  • 77.
    Manell, Elin
    et al.
    Swedish Univ Agr Sci, Dept Clin Sci, Uppsala, Sweden..
    Puuvuori, Emmi
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Svensson, Anna
    Swedish Univ Agr Sci, Dept Clin Sci, Uppsala, Sweden..
    Velikyan, Irina
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Hulsart-Billström, Gry
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Hedenqvist, Patricia
    Swedish Univ Agr Sci, Dept Clin Sci, Uppsala, Sweden..
    Juul Holst, Jens
    Univ Copenhagen, NNF Ctr Basic Metab Res, Copenhagen, Denmark.;Univ Copenhagen, Dept Biomed Sci, Copenhagen, Denmark..
    Jensen Waern, Marianne
    Swedish Univ Agr Sci, Dept Clin Sci, Uppsala, Sweden..
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Exploring the GLP-1-GLP-1R axis in porcine pancreas and gastrointestinal tract in vivo by ex vivo autoradiography2021Inngår i: BMJ Open Diabetes Research & Care, ISSN 2052-4897, Vol. 9, artikkel-id e002083Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Introduction Glucagon-like peptide-1 (GLP-1) increases insulin secretion from pancreatic beta-cells and GLP-1 receptor (GLP-1R) agonists are widely used as treatment for type 2 diabetes mellitus. Studying occupancy of the GLP-1R in various tissues is challenging due to lack of quantitative, repeatable assessments of GLP-1R density. The present study aimed to describe the quantitative distribution of GLP-1Rs and occupancy by endogenous GLP-1 during oral glucose tolerance test (OGTT) in pigs, a species that is used in biomedical research to model humans.

    Research design and methods GLP-1R distribution and occupancy were measured in pancreas and gastrointestinal tract by ex vivo autoradiography using the GLP-1R-specific radioligand 177Lu-exendin-4 in two groups of pigs, control or bottle-fed an oral glucose load. Positron emission tomography (PET) data from pigs injected with 68Ga-exendin-4 in a previous study were used to retrieve data on biodistribution of GLP-1R in the gastrointestinal tract.

    Results High homogenous uptake of 177Lu-exendin-4 was found in pancreas, and even higher uptake in areas of duodenum. Low uptake of 177Lu-exendin-4 was found in stomach, jejunum, ileum and colon. During OGTT, there was no increase in plasma GLP-1 concentrations and occupancy of GLP-1Rs was low. The ex vivo autoradiography results were highly consistent with to the biodistribution of 68Ga-exendin-4 in pigs scanned by PET.

    Conclusion We identified areas with similarities as well as important differences regarding GLP-1R distribution and occupancy in pigs compared with humans. First, there was strong ligand binding in the exocrine pancreas in islets. Second, GLP-1 secretion during OGTT is minimal and GLP-1 might not be an important incretin in pigs under physiological conditions. These findings offer new insights on the relevance of porcine diabetes models.

    Fulltekst (pdf)
    FULLTEXT01
  • 78.
    Monazzam, Azita
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Endokrin tumörbiologi.
    Lau, Joey
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi.
    Li, Su-Chen
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Endokrin tumörbiologi.
    Razmara, Masoud
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Endokrin tumörbiologi.
    Rosenström, Ulrika
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Theranostics.
    Skogseid, Britt
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Endokrin tumörbiologi.
    Increased Expression of GLP-1R in Proliferating Islets of Men1 Mice is Detectable by [Ga-68]Ga-DO3A-VS-Cys(40)- Exendin-4/PET2018Inngår i: Scientific Reports, E-ISSN 2045-2322, Vol. 8, artikkel-id 748Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Multiple endocrine neoplasia type 1 (MEN1) is an endocrine tumor syndrome caused by heterozygous mutations in the MEN1 tumor suppressor gene. The MEN1 pancreas of the adolescent gene carrier frequently contain diffusely spread pre-neoplasias and microadenomas, progressing to macroscopic and potentially malignant pancreatic neuroendocrine tumors (P-NET), which represents the major death cause in MEN1. The unveiling of the molecular mechanism of P-NET which is not currently understood fully to allow the optimization of diagnostics and treatment. Glucagon-like peptide 1 (GLP-1) pathway is essential in islet regeneration, i.e. inhibition of β-cell apoptosis and enhancement of β-cell proliferation, yet involvement of GLP-1 in MEN1 related P-NET has not yet been demonstrated. The objective of this work was to investigate if normal sized islets of Men1 heterozygous mice have increased Glucagon-like peptide-1 receptor (GLP-1R) expression compared to wild type islets, and if this increase is detectable in vivo with positron emission tomography (PET) using [68Ga]Ga-DO3A-VS-Cys40-Exendin-4 (68Ga-Exendin-4). 68Ga-Exendin-4 showed potential for early lesion detection in MEN1 pancreas due to increased GLP1R expression.

    Fulltekst (pdf)
    fulltext
  • 79. Nalin, Lovisa
    et al.
    Selvaraju, Ram K
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Berglund, Marie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap.
    Andréasson, Susanne
    Wikstrand, Anna
    Rydén, Anneli
    Lubberink, Mark
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för nuklearmedicin och PET.
    Kandeel, Fouad
    Nyman, Görel
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Jensen-Waern, Marianne
    Positron emission tomography imaging of the glucagon-like peptide-1 receptor in healthy and streptozotocin-induced diabetic pigs2014Inngår i: European Journal of Nuclear Medicine and Molecular Imaging, ISSN 1619-7070, E-ISSN 1619-7089, Vol. 41, nr 9, s. 1800-1810Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Purpose

    The glucagon-like peptide-1 receptor (GLP-1R) has been proposed as a target for molecular imaging of beta cells. The feasibility of non-invasive imaging and quantification of GLP-1R in pancreas using the positron emission tomography (PET) tracer [68Ga]Ga-DO3A-VS-Cys40-Exendin-4 in non-diabetic and streptozotocin (STZ)–induced diabetic pigs treated with insulin was investigated.

    Methods

    Non-diabetic (n = 4) and STZ-induced diabetic pigs (n = 3) from the same litter were examined. Development of diabetes was confirmed by blood glucose values, clinical examinations and insulin staining of pancreatic sections post mortem. Tissue perfusion in the pancreas and kidneys was evaluated by [15O]water PET/computed tomography (CT) scans. The in vivo receptor specificity of [68Ga]Ga-DO3A-VS-Cys40-Exendin-4 was assessed by administration of either tracer alone or by competition with 3–6.5 μg/kg of Exendin-4. Volume of distribution and occupancy in the pancreas were quantified with a single tissue compartment model.

    Results

    [15O]water PET/CT examinations showed reduced perfusion in the pancreas and kidneys in diabetic pigs. [68Ga]Ga-DO3A-VS-Cys40-Exendin-4 uptake in the pancreas of both non-diabetic and diabetic pigs was almost completely abolished by co-injection of unlabeled Exendin-4 peptide. [68Ga]Ga-DO3A-VS-Cys40-Exendin-4 uptake did not differ between non-diabetic and diabetic pigs. In all animals, administration of the tracer resulted in an immediate increase in the heart rate (HR).

    Conclusion

    Pancreatic uptake of [68Ga]Ga-DO3A-VS-Cys40-Exendin-4 was not reduced by destruction of beta cells in STZ-induced diabetic pigs.

  • 80.
    Persson, Jonas
    et al.
    KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Roslagstullsbacken 21, S-10691 Stockholm, Sweden..
    Puuvuori, Emmi
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Zhang, Bo
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Velikyan, Irina
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Åberg, Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Müller, Malin
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Nygren, Per-Åke
    KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Roslagstullsbacken 21, S-10691 Stockholm, Sweden..
    Ståhl, Stefan
    KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Roslagstullsbacken 21, S-10691 Stockholm, Sweden..
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Löfblom, John
    KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Roslagstullsbacken 21, S-10691 Stockholm, Sweden..
    Discovery, optimization and biodistribution of an Affibody molecule for imaging of CD692021Inngår i: Scientific Reports, E-ISSN 2045-2322, Vol. 11, nr 1, artikkel-id 19151Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Due to the wide scale of inflammatory processes in different types of disease, more sensitive and specific biomarkers are required to improve prevention and treatment. Cluster of differentiation 69 (CD69) is one of the earliest cell surface proteins expressed by activated leukocytes. Here we characterize and optimize potential new imaging probes, Affibody molecules targeting CD69 for imaging of activated immune cells. Analysis of candidates isolated in a previously performed selection from a Z variant E. coli library to the recombinant extracellular domain of human CD69, identified one cross-reactive Z variant with affinity to murine and human CD69. Affinity maturation was performed by randomization of the primary Z variant, followed by selections from the library. The resulting Z variants were evaluated for affinity towards human and murine CD69 and thermal stability. The in vivo biodistribution was assessed by SPECT/CT in rats following conjugation of the Z variants by a DOTA chelator and radiolabeling with Indium-111. A primary Z variant with a K-d of approximately 50 nM affinity to human and murine CD69 was identified. Affinity maturation generated 5 additional Z variants with improved or similar affinity. All clones exhibited suitable stability. Radiolabeling and in vivo biodistribution in rat demonstrated rapid renal clearance for all variants, while the background uptake and washout varied. The variant Z(CD69:4) had the highest affinity for human and murine CD69 (34 nM) as well as the lowest in vivo background binding. In summary, we describe the discovery, optimization and evaluation of novel Affibody molecules with affinity for CD69. Affibody molecule Z(CD69:4) is suitable for further development for imaging of activated immune cells.

    Fulltekst (pdf)
    FULLTEXT01
  • 81.
    Puuvuori, Emmi
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Chiodaroli, Elena
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet.
    Estrada, Sergio
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI.
    Cheung, Pierre
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Lubenow, Norbert
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Vaskulärbiologi.
    Sigfridsson, Jonathan
    PET Center, Center for Medical Imaging, Uppsala University Hospital.
    Romelin, Hampus
    PET Center, Center for Medical Imaging, Uppsala University Hospital.
    Ingvast, Sofie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Cancerimmunterapi.
    Elgland, Mathias
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Liggieri, Francesco
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Cancerimmunterapi.
    Perchiazzi, Gaetano
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Antoni, Gunnar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    PET imaging of neutrophil elastase with 11C-GW457427 in Acute Respiratory Distress Syndrome in pigs2023Inngår i: Journal of Nuclear Medicine, ISSN 0161-5505, E-ISSN 1535-5667, Vol. 64, nr 3, s. 423-429Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Today, there is a lack of clinically available imaging techniques to detect and quantify specific immune cell populations. Neutrophils are one of the first immune cells at the site of inflammation, and they secrete the serine protease neutrophil elastase (NE), which is crucial in the fight against pathogens. However, the prolonged lifespan of neutrophils increases the risk that patients will develop severe complications, such as acute respiratory distress syndrome (ARDS). Here, we evaluated the novel radiolabeled NE inhibitor 11C-GW457427 in a pig model of ARDS, for detection and quantification of neutrophil activity in the lungs. Methods: ARDS was induced by intravenous administration of oleic acid to 5 farm pigs, and 4 were considered healthy controls. The severity of ARDS was monitored by clinical parameters of lung function and plasma biomarkers. Each pig was studied with 11C-GW457427 and PET/CT, before and after pretreatment with the NE inhibitor GW311616 to determine in vivo binding specificity. PET image data were analyzed as SUVs and correlated with immunohistochemical staining for NE in biopsies. Results: The binding of 11C-GW457427 was increased in pig lungs with induced ARDS (median SUVmean, 1.91; interquartile range [IQR], 1.67-2.55) compared with healthy control pigs (P < 0.05 and P = 0.03, respectively; median SUVmean, 1.04; IQR, 0.66-1.47). The binding was especially strong in lung regions with high levels of NE and ongoing inflammation, as verified by immunohisto-chemistry. The binding was successfully blocked by pretreatment of an NE inhibitor drug, which demonstrated the in vivo specificity of 11C-GW457427 (P < 0.05 and P = 0.04, respectively; median SUVmean, 0.60; IQR, 0.58-0.77). The binding in neutrophil-rich tissues such as bone marrow (P < 0.05 and P = 0.04, respectively; baseline median SUVmean, 5.01; IQR, 4.48-5.49; block median SUVmean, 1.57; IQR, 0.95-1.85) and spleen (median SUVmean, 2.14; IQR, 1.19-2.36) was also high in all pigs. Conclusion: 11C-GW457427 binds to NE in a porcine model of oleic acid-induced lung inflammation in vivo, with a specific increase in regional lung, bone marrow, and spleen SUV. 11C-GW457427 is a promising tool for localizing, tracking, and quantifying neutrophil-facilitated inflammation in clinical diagnostics and drug development.

  • 82.
    Puuvuori, Emmi
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Liggieri, Francesco
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper. Uppsala Univ, Dept Surg Sci, Hedenstierna Lab, Uppsala, Sweden..
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Chiodaroli, Elena
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper.
    Sigfridsson, Jonathan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper.
    Romelin, Hampus
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper.
    Ingvast, Sofie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för folkhälso- och vårdvetenskap, Geriatrik. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi. Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Hulsart Billström, Gry
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Ortopedi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Perchiazzi, Gaetano
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Klinisk fysiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Anestesiologi och intensivvård, Hedenstiernalaboratoriet.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Theranostics. Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    PET-CT imaging of pulmonary inflammation using [Ga-68]Ga-DOTA-TATE2022Inngår i: EJNMMI Research, E-ISSN 2191-219X, Vol. 12, nr 1, artikkel-id 19Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Purpose In the characterization of severe lung diseases, early detection of specific inflammatory cells could help to monitor patients' response to therapy and increase chances of survival. Macrophages contribute to regulating the resolution and termination of inflammation and have increasingly been of interest for targeted therapies. [Ga-68]Ga-DOTA-TATE is an established clinical radiopharmaceutical targeting somatostatin receptor subtype 2 (SSTR 2). Since activated macrophages (M1) overexpress SSTR 2, the aim of this study was to investigate the applicability of [Ga-68]Ga-DOTA-TATE for positron emission tomography (PET) imaging of M1 macrophages in pulmonary inflammation. Methods Inflammation in the pig lungs was induced by warm saline lavage followed by injurious ventilation in farm pigs (n = 7). Healthy pigs (n = 3) were used as control. A 60-min dynamic PET scan over the lungs was performed after [Ga-68]Ga-DOTA-TATE injection and [F-18]FDG scan was executed afterward for comparison. The uptake of both tracers was assessed as mean standardized uptake values (SUVmean) 30-60-min post-injection. The PET scans were followed by computed tomography (CT) scans, and the Hounsfield units (HU) were quantified of the coronal segments. Basal and apical segments of the lungs were harvested for histology staining. A rat lung inflammation model was also studied for tracer specificity using lipopolysaccharides (LPS) by oropharyngeal aspiration. Organ biodistribution, ex vivo autoradiography (ARG) and histology samples were conducted on LPS treated, octreotide induced blocking and control healthy rats. Results The accumulation of [Ga-68]Ga-DOTA-TATE on pig lavage model was prominent in the more severely injured dorsal segments of the lungs (SUVmean = 0.91 +/- 0.56), compared with control animals (SUVmean = 0.27 +/- 0.16, p < 0.05). The tracer uptake corresponded to the damaged areas assessed by CT and histology and were in line with HU quantification. The [Ga-68]Ga-DOTA-TATE uptake in LPS treated rat lungs could be blocked and was significantly higher compared with control group. Conclusion The feasibility of the noninvasive assessment of tissue macrophages using [Ga-68]Ga-DOTA-TATE/PET was demonstrated in both porcine and rat lung inflammation models. [Ga-68]Ga-DOTA-TATE has a great potential to be used to study the role and presence of macrophages in humans in fight against severe lung diseases.

    Fulltekst (pdf)
    FULLTEXT01
  • 83.
    Puuvuori, Emmi
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Rokka, Johanna
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för folkhälso- och vårdvetenskap.
    Carlsson, Per-Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Li, Zhanchun
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Eriksson, Jonas
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Potential of [C-11]UCB-J as a PET tracer for islets of Langerhans2021Inngår i: Scientific Reports, E-ISSN 2045-2322, Vol. 11, artikkel-id 24466Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Biomarkers for the measurement of islets of Langerhans could help elucidate the etiology of diabetes. Synaptic vesicle glycoprotein 2 A (SV2A) is a potential marker reported to be localized in the endocrine pancreas. [C-11]UCB-J is a novel positron emission tomography (PET) radiotracer that binds to SV2A and was previously evaluated as a synaptic marker in the central nervous system. Here, we evaluated whether [C-11]UCB-J could be utilized as a PET tracer for the islets of Langerhans in the pancreas by targeting SV2A. The mRNA transcription of SV2A was evaluated in human isolated islets of Langerhans and exocrine tissue. In vitro autoradiography was performed on pancreas and brain sections from rats and pigs, and consecutive sections were immunostained for insulin. Sprague-Dawley rats were examined with PET-MRI and ex vivo autoradiography at baseline and with administration of levetiracetam (LEV). Similarly, pigs were examined with dynamic PET-CT over the pancreas and brain after administration of [C-11]UCB-J at baseline and after pretreatment with LEV. In vivo radioligand binding was assessed using a one-compartment tissue model. The mRNA expression of SV2A was nearly 7 times higher in endocrine tissue than in exocrine tissue (p < 0.01). In vitro autoradiography displayed focal binding of [C-11]UCB-J in the pancreas of rats and pigs, but the binding pattern did not overlap with the insulin-positive areas or with ex vivo autoradiography. In rats, pancreas binding was higher than that in negative control tissues but could not be blocked by LEV. In pigs, the pancreas and brain exhibited accumulation of [C-11]UCB-J above the negative control tissue spleen. While brain binding could be blocked by pretreatment with LEV, a similar effect was not observed in the pancreas. Transcription data indicate SV2A to be a valid target for imaging islets of Langerhans, but [C-11]UCB-J does not appear to have sufficient sensitivity for this application.

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  • 84.
    Puuvuori, Emmi
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Shen, Yunbing
    Hulsart Billström, Gry
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Mitran, Bogdan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab. Antaros Medical AB, Mölndal, Sweden.
    Zhang, Bo
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Cheung, Pierre
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Wegrzyniak, Olivia
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Ingvast, Sofie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Cancerimmunterapi.
    Persson, Jonas
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. KTH Royal Institute of Technology, Stockholm, Sweden.
    Ståhl, Stefan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi. KTH Royal Institute of Technology, Stockholm, Sweden.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Cancerimmunterapi.
    Löfblom, John
    Wermeling, Fredrik
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Antaros Medical AB, Mölndal, Sweden.
    Positron Emission Tomography imaging of CD69 in a murine model of rheumatoid arthritisManuskript (preprint) (Annet vitenskapelig)
  • 85.
    Puuvuori, Emmi
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Shen, Yunbing
    Karolinska Inst, Dept Med, Div Rheumatol, Ctr Mol Med, Stockholm, Sweden.;Karolinska Univ Hosp, Stockholm, Sweden..
    Hulsart-Billström, Gry
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI.
    Mitran, Bogdan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab. Antaros Med AB, Mölndal, Sweden.
    Zhang, Bo
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Cheung, Pierre
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Wegrzyniak, Olivia
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Ingvast, Sofie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Cancerimmunterapi.
    Persson, Jonas
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Stockholm, Sweden.
    Ståhl, Stefan
    KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Stockholm, Sweden..
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Cancerimmunterapi.
    Löfblom, John
    KTH Royal Inst Technol, Dept Prot Sci, Div Prot Engn, Stockholm, Sweden..
    Wermeling, Fredrik
    Karolinska Inst, Dept Med, Div Rheumatol, Ctr Mol Med, Stockholm, Sweden.;Karolinska Univ Hosp, Stockholm, Sweden..
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Antaros Med AB, Mölndal, Sweden.
    Noninvasive PET Detection of CD69-Positive Immune Cells Before Signs of Clinical Disease in Inflammatory Arthritis2024Inngår i: Journal of Nuclear Medicine, ISSN 0161-5505, E-ISSN 1535-5667, Vol. 65, nr 2, s. 294-299Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Rheumatoid arthritis (RA) is the most common inflammatory joint disease, and early diagnosis is key for effective disease management. CD69 is one of the earliest cell surface markers seen at the surface of activated immune cells, and CD69 is upregulated in synovial tissue in patients with active RA. In this study, we evaluated the performance of a CD69-targeting PET agent, [68Ga]Ga-DOTA-ZCAM241, for early disease detection in a model of inflammatory arthritis.

    Methods: A model of inflammatory arthritis was induced by transferring splenocytes from KRN T-cell receptor transgenic B6 mice into T-cell–deficient I-Ag7 major histocompatibility complex class II–expressing recipient mice. The mice were examined longitudinally by [68Ga]Ga-DOTA-ZCAM241 PET/CT before and 3, 7, and 12 d after induction of arthritis. Disease progression was monitored by clinical parameters, including measuring body weight and scoring the swelling of the paws. The uptake of [68Ga]Ga-DOTA-ZCAM241 in the paws was analyzed and expressed as SUVmean. Tissue biopsy samples were analyzed for CD69 expression by flow cytometry or immunostaining for a histologic correlate. A second group of mice was examined by a nonbinding, size-matched Affibody molecule as the control.

    Results: Clinical symptoms appeared 5–7 d after induction of arthritis. The uptake of [68Ga]Ga-DOTA-ZCAM241 in the joints was negligible at baseline but increased gradually after disease induction. An elevated PET signal was found on day 3, before the appearance of clinical symptoms. The uptake of [68Ga]Ga-DOTA-ZCAM241 correlated with the clinical score and disease severity. The presence of CD69-positive cells in the joints and lymph nodes was confirmed by flow cytometry and immunostaining. The uptake of the nonbinding tracer that was the negative control also increased gradually with disease progression, although to a lesser extent than with [68Ga]Ga-DOTA-ZCAM241.

    Conclusion: The uptake of [68Ga]Ga-DOTA-ZCAM241 in the inflamed joints preceded the clinical symptoms in the KRN T-cell transfer model of inflammatory arthritis, in accordance with immunostaining for CD69. [68Ga]Ga-DOTA-ZCAM241 is thus a promising PET imaging marker of activated immune cells in tissue during RA onset.

  • 86.
    Rosestedt, Maria
    et al.
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Velikyan, Irina
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET.
    Rosenström, Ulrika
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Theranostics.
    Estrada, Sergio
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Åberg, Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Weis, Jan
    Uppsala Univ Hosp, Dept Med Phys, Uppsala, Sweden.
    Westerlund, Christer
    Antaros Med AB, Mölndal, Sweden.
    Ingvast, Sofie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Nordeman, Patrik
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Preparativ läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Translationell avbildning med PET. Antaros Med AB, Mölndal, Sweden.
    Radiolabelling and positron emission tomography imaging of a high-affinity peptide binder to collagen type 12021Inngår i: Nuclear Medicine and Biology, ISSN 0969-8051, E-ISSN 1872-9614, Vol. 93, s. 54-62Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Introduction

    Pathological formation of fibrosis, is an important feature in many diseases. Fibrosis in liver and pancreas has been associated to metabolic disease including type 1 and 2 diabetes. The current methods for detecting and diagnosing fibrosis are either invasive, or their sensitivity to detect fibrosis in early stage is limited. Therefore, it is crucial to develop non-invasive methods to detect, stage and study the molecular processes that drive the pathology of liver fibrosis. The peptide LRELHLNNN was previously identified as a selective binder to collagen type I with an affinity of 170 nM. Radiolabelled LRELHLNNN thus constitute a potential PET tracer for fibrosis.

    Method

    LRELHLNNN was conjugated to a DOTA/NOTA moiety via a PEG2-linker. DOTA-PEG2-LRELHLNNN was labelled with Gallium-68 and NOTA- PEG2-LRELHLNNN with aluminium fluoride-18. Biodistribution of [68Ga]Ga-DOTA-PEG2-LRELHLNNN and [18F]AlF-NOTA-PEG2-LRELHLNNN was performed in healthy rats ex vivo and in vivo. The 68Ga-labelled analogue was evaluated in a mouse model of liver fibrosis by PET/MRI-imaging. The human predicted dosimetry of the tracers was extrapolated from rat ex vivo biodistribution studies at 10, 20, 40, 60, 120, 180 min (only fluoride-18) post-injection.

    Results

    The peptides were successfully radiolabelled with gallium-68 and aluminium fluoride-18, respectively. The biodistribution of [68Ga]Ga-DOTA-PEG2-LRELHLNNN and [18F]AlF-NOTA-PEG2-LRELHLNNN was favorable showing rapid clearance and low background binding in organs where fibrosis may develop. Binding of [68Ga]Ga-DOTA-PEG2-LRELHLNNN to fibrotic liver was higher than surrounding tissues in mice with induced hepatic fibrosis. However, the binding was in the range of SUV 0.3, indicating limited targeting of the tracer to liver. The extrapolated human predicted dosimetric profiles of [68Ga]Ga-DOTA-PEG2-LRELHLNNN and [18F]AlF-NOTA-PEG2-LRELHLNNN were beneficial, potentially allowing at least three PET examinations annually.

    Conclusions

    We describe the modification, radiolabelling and evaluation of the collagen type I binding peptide LRELHLNNN. The resulting radiotracer analogues demonstrated suitable biodistribution and dosimetry. [68Ga]Ga-DOTA-PEG2-LRELHLNNN exhibited binding to hepatic fibrotic lesions and is a promising tool for PET imaging of fibrosis.

    Advances in knowledge

    Validation of a new collagen targeting PET tracer.

    Implications for patient care

    Early, non-invasive diagnosis and stratification of fibrosis in order to improve the diagnosis, staging and treatment of patients with diseases involving fibrosis.

    Fulltekst (pdf)
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  • 87.
    Rosqvist, Fredrik
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för folkhälso- och vårdvetenskap, Klinisk nutrition och metabolism.
    Kullberg, Joel
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi. Antaros Medical AB, BioVenture Hub, Mölndal, Sweden.
    Ståhlman, Marcus
    Department of Molecular and Clinical Medicine, Institute of medicine, Sahlgrenska Academy at University of Gothenburg, Sweden..
    Cedernaes, Jonathan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Transplantation och regenerativ medicin. Division of Endocrinology, Metabolism and Molecular Medicine, Northwestern University, Chicago, Illinois.
    Heurling, Kerstin
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi. Antaros Medical AB, BioVenture Hub, Mölndal, Sweden;Wallenberg Centre for Molecular and Translational Medicine and Department of Psychiatry and Neurochemistry, University of Gothenburg, Gothenburg, Sweden.
    Johansson, Hans-Erik
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för folkhälso- och vårdvetenskap, Geriatrik.
    Iggman, David
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för folkhälso- och vårdvetenskap, Klinisk nutrition och metabolism. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska och farmaceutiska vetenskapsområdet, centrumbildningar mm, Centrum för klinisk forskning Dalarna.
    Wilking, Helena
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi.
    Larsson, Anders
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Klinisk kemi.
    Eriksson, Olof
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Antaros Medical AB, BioVenture Hub, Mölndal, Sweden.
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi. Antaros Medical AB, BioVenture Hub, Mölndal, Sweden.
    Straniero, Sara
    Metabolism Unit; Endocrinology, Metabolism and Diabetes, and Integrated CardioMetabolic Center (ICMC), Department of Medicine, Karolinska Institutet at Karolinska University Hospital, Huddinge, Stockholm, Sweden..
    Rudling, Mats
    Metabolism Unit; Endocrinology, Metabolism and Diabetes, and Integrated CardioMetabolic Center (ICMC), Department of Medicine, Karolinska Institutet at Karolinska University Hospital, Huddinge, Stockholm, Sweden..
    Antoni, Gunnar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Lubberink, Mark
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi.
    Orho-Melander, Marju
    Department of Clinical Sciences in Malmö, Lund University Diabetes Center, Lund University, Sweden.
    Borén, Jan
    Department of Molecular and Clinical Medicine, Institute of medicine, Sahlgrenska Academy at University of Gothenburg, Sweden..
    Ahlström, Håkan
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Radiologi. Antaros Medical AB, BioVenture Hub, Mölndal, Sweden.
    Risérus, Ulf
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för folkhälso- och vårdvetenskap, Klinisk nutrition och metabolism.
    Overeating saturated fat promotes fatty liver and ceramides compared to polyunsaturated fat: a randomized trial2019Inngår i: Journal of Clinical Endocrinology and Metabolism, ISSN 0021-972X, E-ISSN 1945-7197, Vol. 104, nr 12, s. 6207-6219Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    CONTEXT: Saturated fat (SFA) versus polyunsaturated fat (PUFA) may promote non-alcoholic fatty liver disease (NAFLD) by yet unclear mechanisms.

    OBJECTIVE: To investigate if overeating SFA- and PUFA-enriched diets lead to differential liver fat accumulation in overweight and obese humans.

    DESIGN: Double-blind randomized trial (LIPOGAIN-2). Overfeeding SFA vs PUFA for 8 weeks, followed by 4 weeks of caloric restriction.

    SETTING: General community.Participants: n=61 overweight or obese men and women.

    INTERVENTION: Muffins high in either palm (SFA)- or sunflower oil (PUFA) were added to the habitual diet.

    MAIN OUTCOME MEASURE: Lean tissue mass (not reported here). Secondary and exploratory outcomes included liver and ectopic fat depots.

    RESULTS: By design, body weight gain was similar in SFA (2.31±1.38 kg) and PUFA (2.01±1.90 kg) groups, P=0.50. SFA markedly induced liver fat content (50% relative increase) along with liver enzymes and atherogenic serum lipids. In contrast, despite similar weight gain, PUFA did not increase liver fat or liver enzymes or cause any adverse effects on blood lipids. SFA had no differential effect on the accumulation of visceral fat, pancreas fat or total body fat compared with PUFA. SFA consistently increased, while PUFA reduced circulating ceramides; changes that were moderately associated with liver fat changes and proposed markers of hepatic lipogenesis. The adverse metabolic effects of SFA were reversed by calorie restriction.

    CONCLUSIONS: Saturated fat markedly induces liver fat and serum ceramides whereas dietary polyunsaturated fat prevent liver fat accumulation, reduce ceramides and hyperlipidemia during excess energy intake and weight gain in overweight individuals.

    Fulltekst (pdf)
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  • 88.
    Rydén, Anneli
    et al.
    Swedish Univ Agr Sci, Fac Vet Med & Anim Sci, Dept Clin Sci, POB 7054, S-75007 Uppsala, Sweden..
    Nyman, Gorel
    Swedish Univ Agr Sci, Fac Vet Med & Anim Sci, Dept Clin Sci, POB 7054, S-75007 Uppsala, Sweden..
    Nalin, Lovisa
    Swedish Univ Agr Sci, Fac Vet Med & Anim Sci, Dept Clin Sci, POB 7054, S-75007 Uppsala, Sweden..
    Andreasson, Susanne
    Swedish Univ Agr Sci, Fac Vet Med & Anim Sci, Dept Clin Sci, POB 7054, S-75007 Uppsala, Sweden..
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Jensen-Waern, Marianne
    Swedish Univ Agr Sci, Fac Vet Med & Anim Sci, Dept Clin Sci, POB 7054, S-75007 Uppsala, Sweden..
    Cardiovascular side-effects and insulin secretion after intravenous administration of radiolabeled Exendin-4 in pigs2016Inngår i: Nuclear Medicine and Biology, ISSN 0969-8051, E-ISSN 1872-9614, Vol. 43, nr 7, s. 397-402Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Introduction: Radiolabeled Exendin-4, a synthetic glucagon-like peptide-1 (GLP-1) analog, is used as a tracer for diagnostic purposes of beta-cells and in experimental animal research. Exendin-4 can be radiolabeled with Ga-68, I-111 n or (99)mTc and used for positron emission tomography (PET) and single-photon emission computed tomography (SPECT) imaging to diagnose insulinomas, visualization of pancreatic beta-cell mass and transplanted Islets of Langerhans. In humans, Exendin-4 is widely used as a therapeutic agent for treatment of type 2 diabetes (T2D). The compound, which is administered subcutaneously (SC) may cause nausea, vomiting and a minor increase in the heart rate (HR). However, possible side-effects on cardiovascular functions after intravenous (IV) administration have not been reported. This study describes the Exendin-4 dose at which cardiovascular side-effects occur in pigs and cynomolgus monkeys. The IV effect of the tracer on insulin secretion is also investigated in pigs. Methods: Seven clinically healthy littermate pigs (40 days old) were used; three of them were made diabetic by streptozotocin (STZ). All pigs underwent PET imaging under general anesthesia to examine the glucagon-like peptide-1 receptor (GLP-1R) in beta-cells with radiolabeled Exendin-4. A baseline tracer dose IV [Ga-68]Exendin-4 (0.025 +/- 0.010 mu g/kg) followed by a competition dose IV [Ga-68]Exendin-4 (3.98 +/- 133 mu g/kg) 60 min later were administered. Blood samples were taken and analyzed for insulin secretion by using ELISA. Cardiovascular and respiratory variables were monitored throughout the experiment. Results: Immediately after administration of the high dose [Ga-68]Exendin-4 the HR rose from 122 14 to 227 +/- 40 bpm (p < 0.01) and from 100 +/- 5 to 181 +/- 13 bpm (p < 0.01) in healthy non -diabetic and diabetes-induced pigs, respectively. The tachycardia was observed for >2 h and one healthy non-diabetic pig suffered cardiac arrest 3 h after the IV [Ga-68]Exendin-4. Arrhythmia was detected by listening to the heart with a stethoscope up to 4 days after the [Ga-68]Exendin-4 injection. In all animals, no effect on the cardiovascular system was registered after the low dose of IV [Ga-68]Exendin-4. Insulin secretion increased (p < 0.05) when IV [Ga-68]Exendin-4 was given in dosages >= 0.14 mu g/kg. Conclusions: Intravenous administration of mu g/kg [Ga-68]Exendin-4 resulted in severe tachycardia and arrhythmias in healthy non -diabetic and diabetes-induced pigs, and the insulin secretion was stimulated in healthy non diabetic animals when >= 0.14 mu g/kg [Ga-68]Exendin-4 was given.

  • 89.
    Samanta, Sumanta
    et al.
    Tampere Univ, Bioengn & Nanomed Lab, Fac Med & Hlth Technol, Tampere 33720, Finland.
    Le Joncour, Vadim
    Univ Helsinki, Translat Canc Med Res Program, Fac Med, Haartmaninkatu 8, Helsinki 00290, Uusimaa, Finland.
    Wegrzyniak, Olivia
    Uppsala universitet, Science for Life Laboratory, SciLifeLab. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi.
    Rangasami, Vignesh K.
    Uppsala universitet, Teknisk-naturvetenskapliga vetenskapsområdet, Kemiska sektionen, Institutionen för kemi - Ångström, Polymerkemi. Tampere Univ, Bioengn & Nanomed Lab, Fac Med & Hlth Technol, Tampere 33720, Finland.
    Ali-Loytty, Harri
    Tampere Univ, Surface Sci Grp, Photon Lab, POB 692, FI-33014 Tampere, Finland.
    Hong, Taehun
    Univ Tokyo, Dept Bioengn, Grad Sch Engn, Bunkyo Ku, 7-3-1 Hongo, Tokyo 1138656, Japan.
    Selvaraju, Ram Kumar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Åberg, Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Hilborn, Jöns
    Uppsala universitet, Teknisk-naturvetenskapliga vetenskapsområdet, Kemiska sektionen, Institutionen för kemi - Ångström, Polymerkemi.
    Laakkonen, Pirjo
    Univ Helsinki, Translat Canc Med Res Program, Fac Med, Haartmaninkatu 8, Helsinki 00290, Uusimaa, Finland.
    Varghese, Oommen P.
    Uppsala universitet, Teknisk-naturvetenskapliga vetenskapsområdet, Kemiska sektionen, Institutionen för kemi - Ångström, Polymerkemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi. Uppsala universitet, Science for Life Laboratory, SciLifeLab.
    Cabral, Horacio
    Univ Tokyo, Dept Bioengn, Grad Sch Engn, Bunkyo Ku, 7-3-1 Hongo, Tokyo 1138656, Japan.
    Oommen, Oommen P.
    Tampere Univ, Bioengn & Nanomed Lab, Fac Med & Hlth Technol, Tampere 33720, Finland.
    Heparin-Derived Theranostic Nanoprobes Overcome the Blood-Brain Barrier and Target Glioma in Murine Model2022Inngår i: Advanced Therapeutics, E-ISSN 2366-3987, Vol. 5, nr 6, artikkel-id 2200001Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    The poor permeability of theranostic agents across the blood-brain barrier (BBB) significantly hampers the development of new treatment modalities for neurological diseases. A new biomimetic nanocarrier is discovered using heparin (HP) that effectively passes the BBB and targets glioblastoma. Specifically, HP-coated gold nanoparticles (HP-AuNPs) are designed that are labeled with three different imaging modalities namely, fluorescein (FITC-HP-AuNP), radioisotope (68)Gallium (Ga-68-HP-AuNPs), and MRI active gadolinium (Gd-HP-AuNPs). The systemic infusion of FITC-HP-AuNPs in three different mouse strains (C57BL/6JRj, FVB, and NMRI-nude) displays excellent penetration and reveals uniform distribution of fluorescent particles in the brain parenchyma (69-86%) with some accumulation in neurons (8-18%) and microglia (4-10%). Tail-vein administration of radiolabeled Ga-68-HP-AuNPs in healthy rats also show Ga-68-HP-AuNP inside the brain parenchyma and in areas containing cerebrospinal fluid, such as the lateral ventricles, the cerebellum, and brain stem. Finally, tail-vein administration of Gd-HP-AuNPs (that displays approximate to threefold higher relaxivity than that of commercial Gd-DTPA) in an orthotopic glioblastoma (U87MG xenograft) model in nude mice demonstrates enrichment of T1-contrast at the intracranial tumor with a gradual increase in the contrast in the tumor region between 1 and 3 h. It is believed, the finding offers the untapped potential of HP-derived-NPs to deliver cargo molecules for treating neurological disorders.

    Fulltekst (pdf)
    FULLTEXT01
  • 90.
    Selvaraju, Ram K.
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för nuklearmedicin och PET.
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Wu, Zhanhong
    Todorov, Ivan
    Shively, Jack
    Kandeel, Fouad
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    In Vivo Imaging of the Glucagonlike Peptide 1 Receptor in the Pancreas with Ga-68-Labeled DO3A-Exendin-42013Inngår i: Journal of Nuclear Medicine, ISSN 0161-5505, E-ISSN 1535-5667, Vol. 54, nr 8, s. 1458-1463Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    The glucagonlike peptide 1 receptor (GLP-1R) is mainly expressed on beta-cells in the Wets of Langerhans and is therefore an attractive target for imaging of the beta-cell mass. In the present study, Ga-68-labeled exendin-4 was evaluated for PET imaging and quantification of GLP-1R in the pancreas. Methods: Dose escalation studies of Ga-68-labeled 1,4,7-tris(carboxymethylaza)cyclododecane-10-azaacetyl (DO3A)-exendin-4 were performed in rats (organ distribution) and cynomolgus monkeys (PET/CT imaging) to determine the GLP-1R-specific tissue uptake in vivo. Pancreatic uptake (as determined by organ distribution) in healthy rats was compared with that in diabetic rats. GLP-1R occupancy in the cynomolgus pancreas was quantified with a 1-tissue-compartment model. Results: In rodents, uptake in the pancreas was decreased from the baseline by up to 90% (P < 0.0001) by coadministration of DO3A-exendin-4 at 100 mu g/kg. Pancreatic uptake in diabetic animals was decreased by more than 80% (P < 0.001) compared with that in healthy controls, as measured by organ distribution. GLP-1R occupancy in the cynomolgus pancreas after coinjection of DO3A-exendin-4 at 0.15-20 mu g/kg ranged from 49% to 97%, as estimated by compartment modeling. Conclusion: These results strongly support the notion that Ga-68-DO3A-exendin-4 uptake in the pancreas is mediated by specific receptor binding. In addition, pancreatic uptake was decreased by selective destruction of beta-cells. This result suggests that GLP-1R can be quantified in vivo, which has major implications for the prospect of imaging of native beta-cells.

  • 91.
    Selvaraju, Ram Kumar
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Nalin, L.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Berglund, Marie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Andreasson, S.
    Wikstrand, A.
    Ryden, A.
    Lubberink, Mark
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för nuklearmedicin och PET.
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Kandeel, F.
    Nyman, G.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Jensen-Waern, M.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Positron Emission Tomography imaging of the glucagon like peptide-1 receptor in healthy and streptozotocin-induced diabetic pigs2014Inngår i: European Journal of Nuclear Medicine and Molecular Imaging, ISSN 1619-7070, E-ISSN 1619-7089, Vol. 41, nr S2, s. S394-S394, artikkel-id P128Artikkel i tidsskrift (Annet vitenskapelig)
  • 92.
    Selvaraju, Ram Kumar
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Nalin, Lovisa
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Berglund, Marie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för nuklearmedicin och PET.
    Ryden, Anneli
    Kandeel, Fouad
    Nyman, Gorel
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Jensen-Waern, Marianne
    PET imaging of the GLP-1 receptor in healthy and streptozotocin-induced diabetic pigs2014Inngår i: Journal of Nuclear Medicine, ISSN 0161-5505, E-ISSN 1535-5667, Vol. 55, nr Suppl. 1, s. 387-Artikkel i tidsskrift (Fagfellevurdert)
  • 93.
    Selvaraju, Ram Kumar
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Espes, Daniel
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi.
    Carlsson, Per-Ola
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinsk cellbiologi. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för medicinska vetenskaper, Endokrin diabetes och metabolism.
    Todorov, I.
    Wu, Z.
    Shively, J.
    Johansson, Lars
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för radiologi.
    Kandeel, F.
    Korsgren, Olle
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Klinisk immunologi.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Pancreatic uptake of [68Ga]DO3A-Exendin4 is mediated by the GLP-1 receptor2012Inngår i: European Journal of Nuclear Medicine and Molecular Imaging, ISSN 1619-7070, E-ISSN 1619-7089, Vol. 39, nr S2, s. S195-S195Artikkel i tidsskrift (Annet vitenskapelig)
  • 94.
    Selvaraju, Ram Kumar
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Velikyan, Irina
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Estrada, Sergio
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Dosimetry of [68Ga]Ga-DO3A-VS-Cys40-Exendin-4 in rat, non-human primate and human2014Inngår i: Journal of Nuclear Medicine, ISSN 0161-5505, E-ISSN 1535-5667, Vol. 55, nr Suppl. 1Artikkel i tidsskrift (Fagfellevurdert)
  • 95.
    Spiegelberg, Diana
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Mortensen, Anja C
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Selvaraju, Ram K
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för Preklinisk PET-MRI.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Avdelningen för Molekylär Avbildning.
    Stenerlöw, Bo
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Nestor, Marika
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Öron-, näs- och halssjukdomar.
    Molecular imaging of EGFR and CD44v6 for prediction and response monitoring of HSP90 inhibition in an in vivo squamous cell carcinoma model.2016Inngår i: European Journal of Nuclear Medicine and Molecular Imaging, ISSN 1619-7070, E-ISSN 1619-7089, Vol. 43, nr 5, s. 974-982Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    PURPOSE: Heat shock protein 90 (HSP90) is essential for the activation and stabilization of numerous oncogenic client proteins. AT13387 is a novel HSP90 inhibitor promoting degradation of oncogenic proteins upon binding, and may also act as a radiosensitizer. For optimal treatment there is, however, the need for identification of biomarkers for patient stratification and therapeutic response monitoring, and to find suitable targets for combination treatments. The aim of this study was to assess the response of surface antigens commonly expressed in squamous cell carcinoma to AT13387 treatment, and to find suitable biomarkers for molecular imaging and radioimmunotherapy in combination with HSP90 inhibition.

    METHODS: Cancer cell proliferation and radioimmunoassays were used to evaluate the effect of AT13387 on target antigen expression in vitro. Inhibitor effects were then assessed in vivo in mice-xenografts. Animals were treated with AT13387 (5 × 50 mg/kg), and were imaged with PET using either (18)F-FDG or (124)I-labelled tracers for EGFR and CD44v6, and this was followed by ex-vivo biodistribution analysis and immunohistochemical staining.

    RESULTS: AT13387 exposure resulted in high cytotoxicity and possible radiosensitization with IC50 values below 4 nM. Both in vitro and in vivo AT13387 effectively downregulated HSP90 client proteins. PET imaging with (124)I-cetuximab showed a significant decrease of EGFR in AT13387-treated animals compared with untreated animals. In contrast, the squamous cell carcinoma-associated biomarker CD44v6, visualized with (124)I-AbD19384 as well as (18)F-FDG uptake, were not significantly altered by AT13387 treatment.

    CONCLUSION: We conclude that AT13387 downregulates HSP90 client proteins, and that molecular imaging of these proteins may be a suitable approach for assessing treatment response. Furthermore, radioimmunotherapy targeting CD44v6 in combination with AT13387 may potentiate the radioimmunotherapy outcome due to radiosensitizing effects of the drug, and could potentially lead to a lower dose to normal tissues.

    Fulltekst (pdf)
    fulltext
  • 96.
    Spiegelberg, Diana
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Mortensen, Anja C.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Selvaraju, Ram Kumar
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Stenerlöw, Bo
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap.
    Scott, A.
    Olivia Newton John Canc Res Inst, Ludwig Inst Canc Res, Melbourne, Vic, Australia.;La Trobe Univ, Melbourne, Vic, Australia..
    Nestor, Marika
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för immunologi, genetik och patologi, Medicinsk strålningsvetenskap. Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för kirurgiska vetenskaper, Öron-, näs- och halssjukdomar.
    Molecular imaging of EGFR and EGFRvIII for prediction and response monitoring of HSP90 inhibition in an in vivo squamous cell carcinoma model2015Inngår i: European Journal of Nuclear Medicine and Molecular Imaging, ISSN 1619-7070, E-ISSN 1619-7089, Vol. 42, nr S1, s. S263-S264Artikkel i tidsskrift (Annet vitenskapelig)
  • 97.
    Strand, Joanna
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Varasteh, Zohreh
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Abrahmsen, L.
    Orlova, Anna
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Tolmachev, Vladimir
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Gallium-68-labeled affibody molecule for PET imaging of PDGFR beta expression in vivo2014Inngår i: European Journal of Nuclear Medicine and Molecular Imaging, ISSN 1619-7070, E-ISSN 1619-7089, Vol. 41, nr S2, s. S262-S262, artikkel-id OP469Artikkel i tidsskrift (Annet vitenskapelig)
  • 98.
    Strand, Joanna
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap. Rudbecklaboratoriet.
    Varasteh, Zohreh
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Abrahmsen, Lars
    Orlova, Anna
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Tolmachev, Vladimir
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Gallium-68-Labeled Affibody Molecule for PET Imaging of PDGFRβ Expression in Vivo2014Inngår i: Molecular Pharmaceutics, ISSN 1543-8384, E-ISSN 1543-8392, Vol. 11, nr 11, s. 3957-3964Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Platelet-derived growth factor receptor β (PDGFRβ) is a transmembrane tyrosine kinase receptor involved, for example, in angiogenesis. Overexpression and excessive signaling of PDGFRβ has been observed in multiple malignant tumors and fibrotic diseases, making this receptor a pharmaceutical target for monoclonal antibodies and tyrosine kinase inhibitors. Successful targeted therapy requires identification of responding patients. Radionuclide molecular imaging would enable determination of the PDGFRβ status in all lesions using a single noninvasive repeatable procedure. Recently, we have demonstrated that the affibody molecule Z09591 labeled with 111In can specifically target PDGFRβ-expressing tumors in vivo. The use of positron emission tomography (PET) as an imaging technique would provide superior resolution, sensitivity, and quantitation accuracy. In this study, a DOTA-conjugated Z09591 was labeled with the generator-produced positron emitting radionuclide 68Ga (T1/2 = 67.6 min, Eβ + max = 1899 keV, 89% β+). 68Ga-DOTA-Z09591 retained the capacity to specifically bind to PDGFRβ-expressing U-87 MG glioma cells. The half-maximum inhibition concentration (IC50) of 68Ga-DOTA-Z09591 (6.6 ± 1.4 nM) was somewhat higher than that of 111In-DOTA-Z09591 (1.4 ± 1.2 nM). 68Ga-DOTA-Z09591 demonstrated specific (saturable) targeting of U-87 MG xenografts in immunodeficient mice. The tumor uptake at 2 h after injection was 3.7 ± 1.7% IA/g, which provided a tumor-to-blood ratio of 8.0 ± 3.1. The only organ with higher accumulation of radioactivity was the kidney. MicroPET imaging provided high-contrast imaging of U-87 MG xenografts. In conclusion, the 68Ga-labeled affibody molecule Z09591 is a promising candidate for further development as a probe for imaging PDGFRβ expression in vivo using PET.

  • 99.
    Syvänen, Stina
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för farmaceutisk biovetenskap.
    Blomquist, Gunnar
    Sprycha, Margareta
    Höglund, A. Urban
    Roman, Magnus
    Eriksson, Olof
    Hammarlund-Udenaes, Margareta
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för farmaceutisk biovetenskap.
    Långström, Bengt
    Uppsala universitet, Teknisk-naturvetenskapliga vetenskapsområdet, Kemiska sektionen, Institutionen för biokemi och organisk kemi.
    Bergström, Mats
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för farmaceutisk biovetenskap.
    Duration and degree of cyclosporin induced P-glycoprotein inhibition in the rat blood-brain barrier can be studied with PET2006Inngår i: NeuroImage, ISSN 1053-8119, E-ISSN 1095-9572, Vol. 32, nr 3, s. 1134-1141Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Active efflux transporters in the blood-brain barrier lower the brain concentrations of many drug molecules and endogenous substances and thus affect their central action. The objective of this investigation was to study the dynamics of the entire inhibition process of the efflux transporter P-glycoprotein (P-gp), using positron emission tomography (PET). The P-gp marker [C-11]verapamil was administered to anesthetized rats as an i.v. bolus dose followed by graded infusions via a computerized pump system to obtain a steady-state concentration of [C-11]verapamil in brain. The P-gp modulator cyclosporin A (CsA) (3, 10 and 25 mg/kg) was administered as a short bolus injection 30 min after the start of the [C-11]verapamil infusion. The CsA pharmacokinetics was studied in whole blood in a parallel group of rats. The CsA blood concentrations were used as input to model P-gp inhibition. The inhibition of P-gp was observed as a rapid increase in brain concentrations of [C-11]verapamil, with a maximum after 5, 7.5 and 17.5 min for the respective doses. The respective increases in maximal [C-11]verapamil concentrations were 1.5, 2.5 and 4 times the baseline concentration. A model in which CsA inhibited P-gp by decreasing the transport of [C-11]verapamil out from the brain resulted in the best fit. Our data suggest that it is not the CsA concentration in blood, but rather the CsA concentration in an effect compartment, probably the endothelial cells of the blood-brain barrier that is responsible for the inhibition of P-gp.

  • 100.
    Tolmachev, Vladimir
    et al.
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Medicinska fakulteten, Institutionen för radiologi, onkologi och strålningsvetenskap, Enheten för biomedicinsk strålningsvetenskap.
    Malmberg, Jennie
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Estrada, Sergio
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Eriksson, Olof
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Orlova, Anna
    Uppsala universitet, Medicinska och farmaceutiska vetenskapsområdet, Farmaceutiska fakulteten, Institutionen för läkemedelskemi, Plattformen för preklinisk PET.
    Development of a I-124-labeled version of the anti-PSMA monoclonal antibody capromab for immunoPET staging of prostate cancer: Aspects of labeling chemistry and biodistribution2014Inngår i: International Journal of Oncology, ISSN 1019-6439, E-ISSN 1791-2423, Vol. 44, nr 6, s. 1998-2008Artikkel i tidsskrift (Fagfellevurdert)
    Abstract [en]

    Correct staging of prostate cancer is an unmet clinical need. Radionuclide targeting of prostate-specific membrane antigen (PSMA) with In-111-labeled capromab pendetide (ProstaScint) is a clinical option for prostate cancer staging. We propose the use of I-124-labeled capromab to decrease the retention of radioactivity in healthy organs (due to the non-residualizing properties of the radiolabel). The use of I-124 as a label should increase imaging sensitivity due to the advantages of PET as an imaging modality. Capromab targets the intracellular domain of PSMA; accumulation of radioactivity in the tumor should not depend on internalization of the antigen/antibody complex. Capromab was iodinated, and its targeting properties were compared with indium labeled counterpart in LNCaP xenografts in dual isotope mode. PSMA-negative xenografts (PC3) were used as a negative control. Radioiodinated capromab bound to PSMA specifically. Biodistribution of I-125/In-111-capromab showed a more rapid clearance of iodine radioactivity from liver, spleen, kidneys, bones, colon tissue, as well as tumors. Maximum tumor uptake (13 +/- 8% ID/g for iodine and 29 +/- 9% ID/g for indium) and tumor-to-non-tumor ratios for both agents were measured 5 days post-injection (pi). High tumor accumulation and low uptake of radioactivity in normal organs were confirmed using microPET/CT 5 days pi of I-124-capromab.

    Fulltekst (pdf)
    Tolmachev_2014_IJO_capromab
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