Samnick S, Richter S, Romeike B F, Heimann A, Feiden W, Kempski O, Kirsch C M
Department of Nuclear Medicine, Saarland University Medical Center, Homburg/Saar, Germany.
Eur J Nucl Med. 2000 Oct;27(10):1543-51. doi: 10.1007/s002590000310.
In developing iodine-123-labelled amino acid derivatives for imaging cerebral gliomas by single-photon emission tomography (SPET), we compared p-[123I]iodo-L-phenylalanine (IPA), L-[123I]iodo-1,2,3,4-tetrahydro-7-hydroxyisoquinoline-3-carboxylic acid (ITIC) and L-3-[123I]iodo-alpha-methyltyrosine (IMT) with regard to their uptake in human glioblastoma T99 and T3868 cells, and thereafter studied the mechanisms promoting the cellular uptake. The potential of the 123I-iodinated agents for use as SPET radiopharmaceuticals was evaluated in healthy experimental rats as well as in rats with stereotactically implanted C6 gliomas. The radiopharmaceutical uptake into glioblastoma cells was rapid, temperature and pH dependent, and linear during the first 5 min. Equilibrium was reached after 15-20 min, except in the case of ITIC, the initial uptake of which gradually decreased from 15 min onwards. The radioactivity concentration in glioma cells following 30-min incubation at 37 degrees C (pH 7.4) varied from 11% to 35% of the total activity per million cells (ITIC < IMT < or = IPA). Competitive inhibition experiments using alpha-(methylamino)-isobutyric acid and 2-amino-2-norbornane-carboxylic acid, known as specific substrates for systems A and L, respectively, as well as representative amino acids preferentially transported by system ASC, indicated that IPA, like IMT, is predominantly mediated by the L and ASC transport systems, while no significant involvement of the A transport system could be demonstrated. By contrast, none of the three principal neutral amino acid transport systems (A, L and ASC) appear to be substantially involved in the uptake of ITIC into glioblastoma cells. Analysis of uptake under conditions that change the cell membrane potential, i.e. in high K+ medium, showed that the membrane potential plays an important role in ITIC uptake. Alteration of the mitochondrial activity by means of valinomycin or nigericin induces a slight increase or decrease in the radiopharmaceutical uptake, suggesting a minor contribution of the mitochondria in the uptake. IPA, IMT and ITIC passed the blood-brain barrier, and thereafter showed efflux from the brain. The radioactivity concentration in healthy rat brain 15 min following intravenous injection varied from 0.07% (ITIC) to 0.27% ID/g (IPA). In comparison, the brain uptake in the stereotactically implanted C6 glioma rats was substantially higher (up to 1.10% ID/g 15 min p.i.), with tumour-to-background ratios greater than 4. These data indicate that IPA and ITIC, like IMT, exhibit interesting biological characteristics which hold promise for in vivo brain tumour investigations by SPET.
在研发用于单光子发射断层扫描(SPET)成像脑胶质瘤的碘-123标记氨基酸衍生物过程中,我们比较了对-[¹²³I]碘-L-苯丙氨酸(IPA)、L-[¹²³I]碘-1,2,3,4-四氢-7-羟基异喹啉-3-羧酸(ITIC)和L-3-[¹²³I]碘-α-甲基酪氨酸(IMT)在人胶质母细胞瘤T99和T3868细胞中的摄取情况,随后研究了促进细胞摄取的机制。在健康实验大鼠以及立体定向植入C6胶质瘤的大鼠中评估了¹²³I标记剂作为SPET放射性药物的潜力。放射性药物摄取到胶质母细胞瘤细胞的过程迅速,依赖温度和pH,且在前5分钟呈线性。15 - 20分钟后达到平衡,但ITIC除外,其初始摄取量从15分钟起逐渐下降。在37℃(pH 7.4)孵育30分钟后,胶质瘤细胞中的放射性浓度为每百万细胞总活性的11%至35%(ITIC < IMT ≤ IPA)。使用α-(甲基氨基)-异丁酸和2-氨基-2-降冰片烷羧酸分别作为系统A和L的特异性底物以及系统ASC优先转运的代表性氨基酸进行的竞争性抑制实验表明,IPA与IMT一样,主要由L和ASC转运系统介导,而未证明A转运系统有显著参与。相比之下,三种主要的中性氨基酸转运系统(A、L和ASC)似乎均未大量参与ITIC摄取到胶质母细胞瘤细胞的过程。在改变细胞膜电位的条件下,即在高钾培养基中分析摄取情况,结果表明膜电位在ITIC摄取中起重要作用。通过缬氨霉素或尼日利亚菌素改变线粒体活性会导致放射性药物摄取略有增加或减少,这表明线粒体在摄取中的贡献较小。IPA、IMT和ITIC能够通过血脑屏障,随后从脑中流出。静脉注射后15分钟,健康大鼠脑中的放射性浓度为0.07%(ITIC)至0.27% ID/g(IPA)。相比之下,立体定向植入C6胶质瘤的大鼠脑中摄取量显著更高(注射后15分钟高达1.10% ID/g),肿瘤与背景比值大于4。这些数据表明,IPA和ITIC与IMT一样,具有有趣的生物学特性,有望用于SPET对脑肿瘤进行体内研究。
