氟化2-硝基咪唑低氧探针N-(2-羟基-3,3,3-三氟丙基)-2-(2-硝基-1-咪唑基)乙酰胺(SR 4554, CRC 94/17)的临床前研制及现状:一种通过磁共振波谱和成像、正电子发射断层扫描测量肿瘤缺氧的无创诊断探针。

Anti-cancer drug design Pub Date : 1998-09-01
E O Aboagye, A B Kelson, M Tracy, P Workman
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引用次数: 0

摘要

缺氧在绝大多数啮齿动物和人类实体瘤中都不同程度地发生。它是由肿瘤血管系统不充分和紊乱引起的,因此氧气输送受损。无创检测肿瘤缺氧的探针在选择生物还原药物治疗、抗血管生成/抗血管治疗和缺氧靶向基因治疗的患者方面具有重要的应用价值。此外,肿瘤缺氧已被证明可以预测人类癌症放疗或化疗后的治疗结果,其潜在机制可能涉及缺氧驱动遗传不稳定并导致肿瘤进展。除肿瘤学外,还可用于中风、缺血性心脏病、周围血管疾病、关节炎和其他疾病。本文综述了一种合理设计用于磁共振波谱(MRS)和磁共振成像(MRI)检测肿瘤缺氧的氟化2-硝基咪唑类N-(2-羟基-3,3,3-三氟丙基)-2-(2-硝基- 1 -咪唑基)乙酰胺(SR 4554, CRC 94/17)的设计、验证、临床前开发和现状。并提出了在正电子发射断层扫描(PET)检测中的应用。设计目标是:(i)具有适当氧化还原电位的硝基,可在缺氧肿瘤细胞中选择性还原和结合;(ii)侧链的亲水性/氢键特性,以限制神经组织的渗透和防止神经毒性;(三)位于代谢稳定位置的三个等效氟原子,以增强MRS/MRI检测。小鼠肝微粒体对SR 4554的抑制依赖于氧含量,最大抑制率为0.48 +/- 0.06%。体外实验显示,SR 4554在缺氧而非缺氧的肿瘤细胞中进行了氮还原,电子能量损失光谱分析显示,SR 4554在多细胞肿瘤球体的缺氧区域有选择性保留。达到了药代动力学设计目标。特别是,通过高效液相色谱法测量,脑组织浓度较低,而肿瘤浓度较高。考虑到整体辛醇/水分配系数,这种限制进入脑肿瘤的程度令人惊讶,这归因于侧链的亲水性/氢键特性。定量磁共振成像(MRS)评估19F信号在小鼠肿瘤和人肿瘤异种移植物中的保留。19F保留指数(FRI);在小鼠肿瘤和人类异种移植物中,6 h时19F信号水平与45 min时的比值分别为0.5 ~ 1.0和0.2 ~ 0.9。SR - 4554保留率与pO2的相关性不呈线性关系,但当FRI > 0.5时,% pO2 <或= 5 mmHg均> 60%,表明FRI高与低氧合水平相关。最后,小鼠全身19F-MRI显示SR 4554及其相关代谢物主要定位于肿瘤、肝脏和膀胱区域。选择性的MRS信号在肿瘤中很容易被检测到,其剂量至少比可能在小鼠中引起毒性的剂量低7倍。我们得出结论,SR 4554作为一种无创MRS/MRI探针用于检测肿瘤缺氧的原理证明已经建立。基于这些有希望的研究,SR 4554已被选择用于临床开发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Preclinical development and current status of the fluorinated 2-nitroimidazole hypoxia probe N-(2-hydroxy-3,3,3-trifluoropropyl)-2-(2-nitro-1-imidazolyl) acetamide (SR 4554, CRC 94/17): a non-invasive diagnostic probe for the measurement of tumor hypoxia by magnetic resonance spectroscopy and imaging, and by positron emission tomography.

Hypoxia occurs to a variable extent in a vast majority of rodent and human solid tumors. It results from an inadequate and disorganized tumor vasculature, and hence an impaired oxygen delivery. A probe for the non-invasive detection of tumor hypoxia could find important utility in the selection of patients for therapy with bioreductive agents, anti-angiogenic/anti-vascular therapies and hypoxia-targeted gene therapy. In addition, tumor hypoxia has been shown to predict for treatment outcome following radio- or chemotherapy in human cancers, the underlying mechanism for which may involve hypoxia driving genetic instability and resulting tumor progression. Beyond oncology, utility can also be envisaged in stroke, ischemic heart disease, peripheral vascular disease, arthritis and other disorders. Design, validation, preclinical development and current status of a fluorinated 2-nitroimidazole, N-(2-hydroxy-3,3,3-trifluoropropyl)-2-(2-nitro-l-imidazolyl) acetamide (SR 4554, CRC 94/17), which has been rationally designed for the measurement of tumor hypoxia by magnetic resonance spectroscopy (MRS) and imaging (MRI), are reviewed. Application in positron emission tomography (PET) detection is also proposed. Design goals were: (i) a nitro group with appropriate redox potential for selective reduction and binding in hypoxic tumor cells; (ii) hydrophilic/hydrogen bonding character in the side chain to limit nervous tissue penetration and prevent neurotoxicity; and (iii) three equivalent fluorine atoms to enhance MRS/MRI detection, located in a metabolically stable position. Reduction of SR 4554 by mouse liver microsomes was dependent on oxygen content, with a half-maximal inhibition at 0.48 +/- 0.06%. SR 4554 underwent nitroreduction by hypoxic but not oxic tumor cells in vitro and electron energy loss spectroscopic analysis showed selective retention in the hypoxic regions of multicellular tumor spheroids. Pharmacokinetic design goals were met. In particular, low brain tissue concentrations were seen in contrast to excellent tumor levels, as measured by high performance liquid chromatography. The extent of this restricted entry to brain tumor was surprising given the overall octanol/water partition coefficient and was attributed to the hydrophilic/hydrogen bonding character of the side chain. Quantitative MRS was used to assess the retention of 19F signal in murine tumors and human tumor xenografts. The 19F retention index (FRI; ratio of 19F signal levels at 6 h relative to that at 45 min) ranged from 0.5 to 1.0 and 0.2 to 0.9 for murine tumors and human xenografts respectively. The correlation between SR 4554 retention and pO2 was not a linear one, but when FRI was > 0.5, the % pO2 < or = 5 mmHg was always > 60%, indicating that high FRI was associated with low levels of oxygenation. Finally, whole body 19F-MRI in mice demonstrated that SR 4554 and related metabolites localized mainly in tumor, liver and bladder regions. A selective MRS signal was readily detectable in tumors at doses at least 7-fold lower than those likely to cause toxicity in mice. We conclude that proof of principle is established for the use of SR 4554 as a non-invasive MRS/MRI probe for the detection of tumor hypoxia. Based on these promising studies, SR 4554 has been selected for clinical development.

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