Glucagonlike Peptide-1 Receptor Imaging in Individuals with Type 2 Diabetes

Hsiaoju S Lee, L. States
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The desire to quantify b-cell mass has been a focus of radiotracer research since the initial first-in-humans studies by Boss et al., which have led to a variety of SPECT and PET radiotracers focused on different targets of glucose metabolism. Initially, Boss described a high-specificity and nanomolar-affinity radioiodinated tracer for the GLP-1 receptor (3). It is assumed from studies by Eng et al. that the GLP-1 receptor density reflects b-cell mass (4). Improvements in the spatial resolution and sensitivity of PET scanners have fueled the recent focus on PET radiotracers for this application. In this issue of The Journal of Nuclear Medicine, the article by Eriksson et al. (5) demonstrates a stepwise approach necessary for GLP-1receptor–targeting radiotracer development from the lab to the clinic. The authors investigated the utility of Ga-labeled 1,4,7-tris(carboxymethylaza)cyclododecane-10-azaacetyl (DO3A)-exendin-4 (Ga-exendin4) in adults with type 2 diabetes (T2D) and its association with b-cell mass in overweight-to-obese T2D individuals, building on prior studies (6,7). Furthermore, the authors provided a simplified imaging protocol, a step toward higher throughput needed for large clinical trials. The strengths of this article include the description of preclinical data collected in vitro and in vivo using nonhuman primates. The in vitro studies define binding specificity and internalization characteristics and were followed by nonhuman primate studies evaluating dose escalation and self-blocking effect. The evaluation of biodistribution and physiology in nonhuman primates provided safety information and guidance for the application in human adults. In addition to the preclinical data, the authors also provided the initial evaluation in overweight-to-obese individuals. This study of 13 human subjects, 12 men and 1 woman, gives information on biodistribution and kinetics in the mostly male subjects. The results of this study show high pancreatic uptake compared with background activity. An unsuspected finding was variability in pancreatic radiotracer uptake across patients. This prompted further investigation, which revealed no association of uptake with pancreatic volume or patient age, as b-cell mass is thought to be uniformly distributed and to decrease with age. The self-blocking evaluation described in this paper is an important analysis used in the evaluation of a novel radiotracer to show strong binding in the presence of cold peptide, representing endogenous proteins or administered medication. This competitive binding is of great importance because the treatment dose of exenatide is in the microgram range. The authors studied the effect of higher mass by coinjecting the study participants with up to 0.2 mg/kg. The study team did not observe a difference in the volume of distribution at the lower dose; however, a decrease in binding was seen at 0.45 mg/kg. We found this information encouraging for the development of an F-labeled exendin-4 analog, which suffered the drawback of requiring a higher amount of labeling precursor and difficulties of purification. Compared with Ga, F-labeled tracers offer several distinct advantages, including longer half-life (118 vs. 60 min), higher amount of starting activity (cyclotron bombardment vs. limit on the Ge generator synthesis), and ideal imaging qualities. All warrant the need to develop an F-labeled exendin-4 analog. A successful F-labeled exendin-4 analog can also enable the distribution of large-scale, multicenter trials needed for tackling the complex question of b-cell mass quantification and monitoring and provides less focus on sophisticated equipment and expertise (cyclotron and radiochemist) while still allowing joint efforts in research. The proposed goal of this study was achieved by providing a recommendation for a protocol to be used in human subjects for subsequent phase II and III trials in adults. This phase I study also evaluated the safety and utility of a safe dose range, resulting in a proposed dose. Technical efficacy was achieved by providing image generation and procedural feasibility, which is addressed in the discussion. A limitation of this study is related to sample size. Although a phase I study does not require a control population or randomization, a larger cohort pool enables the establishment of a better baseline. The small sample size makes it impractical to consider a variety of subject characteristics. Further investigations should evaluate female subjects and subjects of racial backgrounds known to have a high incidence of diabetes. Received Nov. 19, 2021; revision accepted Jan. 12, 2022. For correspondence or reprints, contact Lisa J. States (states@chop.edu). 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引用次数: 0

Abstract

Radiolabeled exendin 4, the glucagonlike peptide-1 (GLP-1) receptor agonist, has great prospects for imaging and perhaps quantification of pancreatic b-cells. The GLP-1 receptor is found in high density in the pancreas and liver and plays a key role in postprandial blood glucose homeostasis, including stimulation of insulin synthesis and promotion of b-cell proliferation. b-cells constitute only a small volume of the pancreatic mass, comprising up to 2% of the pancreatic mass and 65%–80% of endocrine cells in the islets of Langerhans. A synthetic peptide agonist of the GLP-1 receptor, exendin-4, also known as exenatide, is used for the treatment of diabetes mellitus, making it an ideal peptide for radiotracer development (1,2). The desire to quantify b-cell mass has been a focus of radiotracer research since the initial first-in-humans studies by Boss et al., which have led to a variety of SPECT and PET radiotracers focused on different targets of glucose metabolism. Initially, Boss described a high-specificity and nanomolar-affinity radioiodinated tracer for the GLP-1 receptor (3). It is assumed from studies by Eng et al. that the GLP-1 receptor density reflects b-cell mass (4). Improvements in the spatial resolution and sensitivity of PET scanners have fueled the recent focus on PET radiotracers for this application. In this issue of The Journal of Nuclear Medicine, the article by Eriksson et al. (5) demonstrates a stepwise approach necessary for GLP-1receptor–targeting radiotracer development from the lab to the clinic. The authors investigated the utility of Ga-labeled 1,4,7-tris(carboxymethylaza)cyclododecane-10-azaacetyl (DO3A)-exendin-4 (Ga-exendin4) in adults with type 2 diabetes (T2D) and its association with b-cell mass in overweight-to-obese T2D individuals, building on prior studies (6,7). Furthermore, the authors provided a simplified imaging protocol, a step toward higher throughput needed for large clinical trials. The strengths of this article include the description of preclinical data collected in vitro and in vivo using nonhuman primates. The in vitro studies define binding specificity and internalization characteristics and were followed by nonhuman primate studies evaluating dose escalation and self-blocking effect. The evaluation of biodistribution and physiology in nonhuman primates provided safety information and guidance for the application in human adults. In addition to the preclinical data, the authors also provided the initial evaluation in overweight-to-obese individuals. This study of 13 human subjects, 12 men and 1 woman, gives information on biodistribution and kinetics in the mostly male subjects. The results of this study show high pancreatic uptake compared with background activity. An unsuspected finding was variability in pancreatic radiotracer uptake across patients. This prompted further investigation, which revealed no association of uptake with pancreatic volume or patient age, as b-cell mass is thought to be uniformly distributed and to decrease with age. The self-blocking evaluation described in this paper is an important analysis used in the evaluation of a novel radiotracer to show strong binding in the presence of cold peptide, representing endogenous proteins or administered medication. This competitive binding is of great importance because the treatment dose of exenatide is in the microgram range. The authors studied the effect of higher mass by coinjecting the study participants with up to 0.2 mg/kg. The study team did not observe a difference in the volume of distribution at the lower dose; however, a decrease in binding was seen at 0.45 mg/kg. We found this information encouraging for the development of an F-labeled exendin-4 analog, which suffered the drawback of requiring a higher amount of labeling precursor and difficulties of purification. Compared with Ga, F-labeled tracers offer several distinct advantages, including longer half-life (118 vs. 60 min), higher amount of starting activity (cyclotron bombardment vs. limit on the Ge generator synthesis), and ideal imaging qualities. All warrant the need to develop an F-labeled exendin-4 analog. A successful F-labeled exendin-4 analog can also enable the distribution of large-scale, multicenter trials needed for tackling the complex question of b-cell mass quantification and monitoring and provides less focus on sophisticated equipment and expertise (cyclotron and radiochemist) while still allowing joint efforts in research. The proposed goal of this study was achieved by providing a recommendation for a protocol to be used in human subjects for subsequent phase II and III trials in adults. This phase I study also evaluated the safety and utility of a safe dose range, resulting in a proposed dose. Technical efficacy was achieved by providing image generation and procedural feasibility, which is addressed in the discussion. A limitation of this study is related to sample size. Although a phase I study does not require a control population or randomization, a larger cohort pool enables the establishment of a better baseline. The small sample size makes it impractical to consider a variety of subject characteristics. Further investigations should evaluate female subjects and subjects of racial backgrounds known to have a high incidence of diabetes. Received Nov. 19, 2021; revision accepted Jan. 12, 2022. For correspondence or reprints, contact Lisa J. States (states@chop.edu). COPYRIGHT© 2022 by the Society of Nuclear Medicine andMolecular Imaging. DOI: 10.2967/jnumed.121.263171
2型糖尿病患者胰高血糖素样肽-1受体成像
放射标记的延伸蛋白4是胰高血糖素样肽-1 (GLP-1)受体激动剂,在胰腺b细胞成像和定量方面具有很大的前景。GLP-1受体在胰腺和肝脏中密度较高,在餐后血糖稳态中起关键作用,包括刺激胰岛素合成和促进b细胞增殖。b细胞仅占胰腺肿块的一小部分,占胰腺肿块的2%,占朗格汉斯胰岛内分泌细胞的65%-80%。一种合成的GLP-1受体的肽激动剂exendin-4,也称为exenatide,用于治疗糖尿病,使其成为开发放射性示踪剂的理想肽(1,2)。自Boss等人首次进行人体研究以来,量化b细胞质量的愿望一直是放射性示踪剂研究的焦点,这导致了各种SPECT和PET放射性示踪剂专注于葡萄糖代谢的不同靶标。最初,Boss描述了一种针对GLP-1受体的高特异性和纳米级亲和力的放射性碘示踪剂(3)。根据Eng等人的研究,假设GLP-1受体密度反映了b细胞质量(4)。PET扫描仪空间分辨率和灵敏度的提高推动了最近对PET放射性示踪剂应用的关注。在这一期的《核医学杂志》上,Eriksson等人(5)的文章展示了glp -1受体靶向放射性示踪剂从实验室到临床的逐步开发所必需的方法。作者在先前的研究基础上,研究了ga标记的1,4,7-三(羧甲基化)环十二烷-10-氮杂乙酰(DO3A)- exendin4 (Ga-exendin4)在2型糖尿病(T2D)成人患者中的效用,以及它与超重至肥胖T2D患者b细胞质量的关系(6,7)。此外,作者还提供了一种简化的成像方案,这是向大型临床试验所需的更高通量迈出的一步。本文的优势包括描述在体外和体内使用非人灵长类动物收集的临床前数据。体外研究确定了结合特异性和内化特性,随后进行了非人类灵长类动物研究,评估剂量递增和自阻断效应。非人灵长类动物的生物分布和生理评价为其在成人中的应用提供了安全性信息和指导。除了临床前数据,作者还提供了超重到肥胖个体的初步评估。这项研究对13名人类受试者,12名男性和1名女性,提供了生物分布和动力学的信息,主要是男性受试者。本研究结果显示,与背景活性相比,胰腺摄取较高。一个意想不到的发现是患者胰腺放射性示踪剂摄取的变异性。这促使了进一步的研究,发现摄取与胰腺体积或患者年龄无关,因为b细胞团块被认为是均匀分布的,并随着年龄的增长而减少。本文中描述的自阻断评价是一种重要的分析,用于评估一种新型放射性示踪剂,以显示在冷肽,代表内源性蛋白质或给药的存在下的强结合。这种竞争性结合是非常重要的,因为艾塞那肽的治疗剂量在微克范围内。作者通过向研究参与者共注射高达0.2 mg/kg的剂量来研究更高质量的影响。研究小组在较低剂量下没有观察到分布体积的差异;然而,在0.45 mg/kg时,结合力下降。我们发现这一信息对f标记的exendin-4类似物的开发是鼓舞人心的,该类似物的缺点是需要更多的标记前体和纯化困难。与Ga相比,f标记的示踪剂具有几个明显的优势,包括更长的半衰期(118比60分钟),更高的起始活性(回旋加速器轰击与锗发生器合成的限制),以及理想的成像质量。所有这些都证明需要开发f标记的exendin-4模拟。一个成功的f标记exendin-4模拟物也可以使大规模、多中心试验的分布成为可能,这些试验需要解决b细胞质量定量和监测的复杂问题,并且在允许联合研究的同时,减少对复杂设备和专业知识(回旋加速器和放射化学家)的关注。本研究提出的目标是通过为后续成人II期和III期试验中用于人类受试者的方案提供建议来实现的。该I期研究还评估了安全剂量范围的安全性和效用,得出了建议剂量。通过提供图像生成和程序可行性来实现技术有效性,并在讨论中加以说明。本研究的局限性与样本量有关。 虽然一期研究不需要对照人群或随机化,但更大的队列池可以建立更好的基线。小样本量使得考虑各种主题特征变得不切实际。进一步的调查应评估女性受试者和已知糖尿病高发种族背景的受试者。2021年11月19日收到;修订于2022年1月12日接受。如需通信或转载,请联系Lisa J. States (states@chop.edu)。核医学与分子成像学会版权所有©2022。DOI: 10.2967 / jnumed.121.263171
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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