131I标记Tyr-GX1在荷瘤裸鼠体内分布和显像研究

目的:设计、合成酪氨酸(Tyr)修饰的肿瘤血管靶向肽GX1,研究131I标记短肽Tyr-GX1在荷人胃癌裸鼠体内的生物学分布与显像,探讨131I-Tyr-GX1短肽作为肿瘤血管靶向诊治药物的可能性.方法:利用Iodogen碘标法对Tyr-GX1进行131I标记,检测其标记率和体内外稳定性;建立荷人胃癌裸鼠动物模型,尾静脉注射标记肽,分别进行体内生物学分布实验和肿瘤显像实验,结果用PASW Statistics 18.0统计软件进行分析.结果:1).纸层析法结果计算表明,131I-Tyr-GX1肽的标记率和放化纯均达90％以上;24 h稳定性测试表明,131I-Tyr-GX1在室温下存放以及与人血清、鼠血清、PBS等溶液混合,其标记率仍然都维持在90％左右,说明其具有良好的体内外稳定性;2).荷瘤裸鼠体内生物学分布研究显示:标记肽在荷瘤裸鼠双肾放射性计数测量最高;其次是肝脏、肿瘤等组织;脑、骨、肌肉组织放射性计数含量较低,给药24 h时,肿瘤/肌肉(T/M)、肿瘤/血液(T/B1)、肿瘤/脑组织(T/Br)的放射性比值分别是5.78、4.06和23.01;3).体内SPECT显像结果显示:尾静脉注射131I-Tyr-GX1肽后4h肿瘤部位已开始显影,并随时间的延长,显像逐渐清楚,至18h时,肿瘤显像最清晰.结论:应用Iodogen碘标法成功标记Tyr-GX1短肽;尾静脉注射131I-Tyr-GX1后,肿瘤部位可以出现放射性浓聚,表明131I-Tyr-GX1短肽可以靶向结合于肿瘤部位,有望成为新一种胃肠道肿瘤诊断与治疗的药物.     

^131I标记Tyr-GX1在荷瘤裸鼠体内分布和显像研究

目的：设计、合成酪氨酸（Tyr）修饰的肿瘤血管靶向肽GX1,研究^131I标记短肽Tyr-GX1在荷人胃癌裸鼠体内的生物学分布与显像,探讨^131I-Tyr-GX1短肽作为肿瘤血管靶向诊治药物的可能性。方法：利用Iodogen碘标法对Tyr-GX1进行131I标记,检测其标记率和体内外稳定性;建立荷人胃癌裸鼠动物模型,尾静脉注射标记肽,分别进行体内生物学分布实验和肿瘤显像实验,结果用PASW Statistics18.0统计软件进行分析。结果：1）.纸层析法结果计算表明,^131I-Tyr-GX1肽的标记率和放化纯均达90%以上;24 h稳定性测试表明,^131I-Tyr-GX1在室温下存放以及与人血清、鼠血清、PBS等溶液混合,其标记率仍然都维持在90%左右,说明其具有良好的体内外稳定性;2）.荷瘤裸鼠体内生物学分布研究显示：标记肽在荷瘤裸鼠双肾放射性计数测量最高;其次是肝脏、肿瘤等组织;脑、骨、肌肉组织放射性计数含量较低,给药24 h时,肿瘤/肌肉（T/M）、肿瘤/血液（T/Bl）、肿瘤/脑组织（T/Br）的放射性比值分别是5.78、4.06和23.01;3）.体内SPECT显像结果显示：尾静脉注射^131I-Tyr-GX1肽后4 h肿瘤部位已开始显影,并随时间的延长,显像逐渐清楚,至18 h时,肿瘤显像最清晰。结论：应用Iodogen碘标法成功标记Tyr-GX1短肽;尾静脉注射^131I-Tyr-GX1后,肿瘤部位可以出现放射性浓聚,表明^131I-Tyr-GX1短肽可以靶向结合于肿瘤部位,有望成为新一种胃肠道肿瘤诊断与治疗的药物。     

乳腺癌荷瘤鼠99mTc-DOTANOC显像与生长抑素受体表达水平的相关性研究

目的:探讨乳腺癌荷瘤鼠模型中肿瘤组织中的生长押素受体(SSTR)的表达水平与99mTc-DOTANOC显像的相关性研究.方法:配体交换法标记99mTc-DOTANOC,通过尾静脉注射乳腺癌荷瘤鼠模型,行99mTc-DOTANOC显像,勾画ROI计算肿瘤与对侧正常组织(T/NT)的放射性比值并测定肿瘤及主要脏器单位组织的放射性摄取百分值(%ID/g),采用逆转录聚合酶反应(RT-PCR)检测肿瘤组织中各SSTR亚型mRNA的表达水平,对SSTR亚型表达水平与T/NT放射性摄取比值进行相关性研究.结果:99mTc-DOTANOC乳腺癌荷瘤鼠模型显像示肿瘤部位有较高的放射性浓聚,与对侧正常组织T/NT比值较高,4h达到2.41±0.21;99mTc-DOTANOC荷瘤鼠体内生物分布示药物在肿瘤部位有较高的摄取;RT-PCR示乳腺癌组织中有着丰富的SSTR表达,SSTR3和SSTR2亚型表达水平较高,两者mRNA的表达水平与荷瘤鼠显像T/NT比值呈正相关(两者分别r=0.94,r=81,P<0.05).结论:乳腺癌细胞株MDA-MB-435 高表达SSTR2和SSTR3,其中SSTR3和SSTR2 mRNA表达水平与肿瘤组织对99mTc-DOTANOC的摄取呈正相关.第三代生长抑素类似物99mTc-DOTANOC受体显像对乳腺癌有较好的影像诊断价值.     

利用小动物 SPECT／CT 和99m锝-葡糖二酸评估急性缺血坏死心肌动物

目的：利用99m锝-葡糖二酸（99mTc-Glucarate）和小动物SPECT/CT评估大鼠急性心肌缺血再灌注损伤后缺血坏死心肌的位置和范围。方法建立大鼠急性缺血再灌注损伤模型,手术1 d后尾静脉注射99m Tc-Glucarate,注射30 min后利用小动物SPECT/CT融合技术分析99m锝-葡糖二酸标记的心肌组织的位置和范围,并与氯化三苯基四氮唑（ triphenyltetrazolium chloride ,TTC）染色法标记的缺血坏死心肌比较。结果小动物SPECT/CT结果显示手术组心肌坏死部位的99m锝-葡糖二酸的放射性摄取率（心肝比值1.90±0.33）明显高于正常组大鼠（ P＜0.05）,利用小动物SPECT/CT融合技术定位的缺血坏死心肌范围和TTC染色法的测量结果呈线性相关（R2＝0.964）。结论通过99m锝-葡糖二酸可以特异性地标记急性缺血坏死心肌,利用小动物SPECT/CT融合技术可以无创性地分析急性缺血坏死心肌的位置和范围。     

单氨三乙酰L-甲硫氨酸的合成

<正> 目前用于诊断肿瘤的化学显影剂中,重要的类型之一就是和肿瘤有关的放射性化合物,如~(75)Se-甲硫氨酸、~(13)N-谷氨酸、~(99m)Tc-谷氨酸等。我们合成了能与~(99m)Tc螯合的配位体——单氨三乙酰L 甲硫氨酸。肿瘤组织一般有很高的蛋白质和核酸代谢活性,氨基酸作为代谢物的前体之一,对肿瘤具有亲合性。将L 甲硫氨酸进行酰化,目的是通过酰胺键连接上易与~(99m)Tc螯合的基团,致使此化合物既保持氨基酸的性质,又     

单光子发射计算机断层扫描肺灌注显像(SPECT/CT)在肺恶性肿瘤放疗中 的应用进展

放射性肺损伤是肺恶性肿瘤放疗后常见的并发症,其限制肺恶性肿瘤的放疗剂量并影响总体疗效及患者生存质量。本文复习放射性肺损伤发生机制及影响因素,分析剂量体积直方图、肺功能测定、TGF-β1等临床常用放射性肺损伤评估指标的利弊。参考近年文献,总结了单光子发射计算机断层扫描肺灌注显像(SPECT/CT)在肺恶性肿瘤放疗中的应用,从其原理、区域肺功能的显像、对放疗的评估与指导应用几方面阐述。认为SPECT/CT能实时反映区域肺功能、肺功能改变以及其解剖定位,可在放疗中起监测作用,对准确评估肺功能、预测放疗后肺损伤,优化放疗计划有重要价值。SPECT/CT肺灌注显像还需要多中心、大样本、长时间随访资料进一步深入研究。     

肺腺癌脑转移动物模型的生物发光成像和SPECT/CT的比较

目的利用稳定表达荧光素酶的luc+-PC-9人肺腺癌细胞建立肺癌脑转移动物模型,比较生物发光成像和18F-FDG(18F-fluorodeoxyglucose,18F-氟代脱氧葡糖)SPECT/CT在肺癌转移模型中的评估作用。方法将luc+-PC-9细胞悬液经左心室注入BALB/c裸鼠建立肺癌脑转移模型,分别在第4、5周行生物发光成像、~(18)F-FDG SPECT/CT检查观察裸鼠成瘤情况,以HE染色病理结果为金标准比较两种方法在肺癌转移模型中的作用。结果经左心室注射luc+-PC-9细胞建立肺癌脑转移模型,脑转移成功率85%。肿瘤细胞的个数与发光强度呈正相关,具有较好的线性关系(R2=0.96)。生物发光成像能在颅脑、脊柱和股骨观察到荧光信号,病理结果证实为转移灶。~(18)F-FDG SPECT/CT在脑组织未见明显的代谢浓聚灶,在股骨或脊柱发现代谢浓聚灶,且病理证实均有骨髓转移。结论左心室注射法是建立人肺腺癌脑转移模型的可靠方法。生物发光成像系统在检测脑转移和骨转移具有较高的灵敏度和特异度,能实现实时、动态、无创观察转移瘤的生长情况;~(18)F-FDG SPECT/CT在检测脑转移灶并不具有优势,更适合于检测骨转移灶。     

高压氧在放射性核素治疗大鼠种植癌后乏氧研究

目的:研究大鼠种植癌在高压氧(HBO)干预及放射治疗前后99mTc-HL91乏氧显像的变化,并探讨其与病理学改变之间的关系,为HBO联合放射性药物对恶性肿瘤治疗效果提供实验支持。方法:建立肿瘤株walker-256细胞大鼠皮下种植癌的动物模型,60只荷瘤大鼠随机分为四组:对照组,高压氧(HBO)组、胶体磷[32P]酸铬和HBO+胶体磷[32P]酸铬组。尾静脉注射99mTc-HL91 37MBq(0.1 mL),4 h后利用SPECT显像,计算肿瘤组织与对侧相应部位放射性计数比值(T/NT),显像当日游标卡尺测量肿瘤最大长径(a)和最大垂直横径(b),计算肿瘤体积以及治疗后不同时间的肿瘤生长率(f)。最后一次显像结束后处死全部模型大鼠,取肿瘤组织制成病理切片,观察各组大鼠肿瘤细胞的凋亡情况。比较实验各组T/NT与肿瘤生长率(f)以及凋亡的关系。结果:肿瘤99mTc-HL91显像良好,肿瘤部位与对侧相应部位具有较高的放射性计数比。治疗后大鼠肿瘤的乏氧区域及肿瘤体积均减少,以HBO+胶体磷[32P]酸铬组为著,T/NT与f呈正相关;大鼠肿瘤的细胞凋亡数明显高于对照组,以HBO+胶体磷[32P]酸铬组增加明显,治疗后T/NT与大鼠肿瘤细胞的凋亡数呈负相关。结论:HBO在放射性核素治疗大鼠种植癌中起到协同作用,通过99mTc-HL91乏氧显像观察HBO干预后胶体磷[32P]酸铬治疗肿瘤效果,从而为二者联合在肿瘤治疗的应用提供依据。     

131Ⅰ－McAbJH_（107）在载人肝癌BEL－7402裸鼠体内的放射免疫显像分析

用氯胺Ｔ碘标技术标记抗人肝癌单克隆抗体ＪＨ１０７（ＭｃＡｂＪＨ１０７）,观测其在载人肝癌ＢＥＬ７４０２裸鼠模型上的分布显像情况,氯胺Ｔ碘标法标记率５０％。每鼠腹腔注射２００Ｃｉ１３１Ⅰ－ＭｃＡｂＪＨ１０７,放射性物质第２４ｈ开始在肿瘤部位浓聚、逐步加强,９６ｈ达高峰,肿瘤组织较清楚显像并维持至１４８ｈ;同时周围组织放射性本底逐步减弱、消失。对照组１３１Ⅰ－ＮＩｇＧ呈全身均匀分布。无明显放射性物质浓聚及清楚显像。在４８ｈ和９６ｈ,１３１Ⅰ－ＭｃＡｂＪＨ１０７在１２种正常组织（脑除外）的Ｔ／ＮＴ均值分别为３．３８和６．２６,而１３１Ⅰ－ＮＩｇＧ的Ｔ／ＮＴ均值均低于１．０。     

肿瘤/肝脏比值在~(18)F-FDG符合线路SPECT/CT显像在肺癌诊断中的价值

目的:探讨18F-FDG符合线路SPECT/CT显像在肺癌病灶的检测能力以及肿瘤/肝脏比值对肺部良恶性病灶及胸部小病灶诊断的临床价值。方法:回顾性分析2011年6月至2013年4月期间于西安交通大学第一附属医院行18F-FDG符合线路SPECT/CT显像的肺癌疑诊患者41例CT测量肺部原发病灶最大直径4.16±2.81厘米(最小直径1.3厘米,最大直径16厘米),以病理结果作为判断标准,通过t检验及接受者操作特征曲线(receiver operating characteristic,ROC)研究18F-FDG符合线路SPECT/CT显像对肺部病灶、肺及纵膈小病灶的诊断价值。结果:18F-FDG符合线路SPECT/CT显像肺部良恶性病灶的肿瘤/肌肉(T/N)、肿瘤/肝脏(T/L)比值差异均具有显著统计学意义(P0.01),T/L比值在肺部良恶性病灶和肺及纵膈最大横径小于3 cm的病灶ROC曲线的曲线下面积分别为0.857、0.810,均大于T/N比值相应的ROC曲线下面积(分别为0.825、0.760)。T/N=3.5为界值时,诊断肺部病灶的灵敏度为90%,特异度为71.4%,准确度为0.614;诊断最大横径小于3 cm病灶的灵敏度为70%,特异度为80%,准确度为0.50。T/L=2.3时诊断肺部病灶的灵敏度为80%,特异度为85.7%,准确度为0.657。T/L=1.6时诊断最大横径小于3 cm病灶的灵敏度为90%,特异度为80%,准确度为0.70。结论:T/N=3.5为界值时,对于肺部病灶及肺及最大横径小于3 cm病灶良恶性的鉴别能力较好。T/L比值对于肺部良恶性病灶和肺及纵膈最大横径小于3 cm的病灶诊断价值均高于传统常用的T/N比值,具有较高的准确性,可以良好的应用于18F-FDG符合线路SPECT/CT显像对肺癌的诊断中。     

The synthesis of pteroyl-lys conjugates and its application as Technetium-99m labeled radiotracer for folate receptor-positive tumor targeting

Aiming to develop a new ^99mTc-labeled folate derivative for FR-positive tumor imaging, a simpler method has been established to synthesize the folate-drug conjugates with free α-carboxyl group. In this study, the conjugate pteroyl-lys-HYNIC was synthesized and labeled with ^99mTc using tricine and TPPTS as co-ligands. The radiochemical purity of the final complex ^99mTc(HYNIC-lys-pteroyl)(tricine/TPPTS), 5 was high (>98%), and it remained stable in saline and plasma over 6 h after preparation. The biologic evaluation results showed that the ^99mTc labeled pteroyl-lys conjugate was able to specifically target the FR-positive tumor cells and tissues both in vitro and in vivo, highlighting its potential as an effective folate receptor targeted agent for tumor imaging.     

3D image-based dosimetry for Yttrium-90 radioembolization of hepatocellular carcinoma: Impact of imaging method on absorbed dose estimates

BackgroundTo improve therapy outcome of Yttrium-90 selective internal radiation therapy (⁹⁰Y SIRT), patient-specific post-therapeutic dosimetry is required. For this purpose, various dosimetric approaches based on different available imaging data have been reported. The aim of this work was to compare post-therapeutic 3D absorbed dose images using Technetium-99m (^99mTc) MAA SPECT/CT, Yttrium-90 (⁹⁰Y) bremsstrahlung (BRS) SPECT/CT, and ⁹⁰Y PET/CT.MethodsTen SIRTs of nine patients with unresectable hepatocellular carcinoma (HCC) were investigated. The ^99mTc SPECT/CT data, obtained from ^99mTc-MAA-based treatment simulation prior to ⁹⁰Y SIRT, were scaled with the administered ⁹⁰Y therapy activity. 3D absorbed dose images were generated by dose kernel convolution with scaled ^99mTc/⁹⁰Y SPECT/CT, ⁹⁰Y BRS SPECT/CT, and ⁹⁰Y PET/CT data of each patient. Absorbed dose estimates in tumor and healthy liver tissue obtained using the two SPECT/CT methods were compared against ⁹⁰Y PET/CT.ResultsThe percentage deviation of tumor absorbed dose estimates from ⁹⁰Y PET/CT values was on average −2 ± 18% for scaled ^99mTc/⁹⁰Y SPECT/CT, whereas estimates from ⁹⁰Y BRS SPECT/CT differed on average by −50 ± 13%. For healthy liver absorbed dose estimates, all three imaging methods revealed comparable values.ConclusionThe quantification capabilities of the imaging data influence ⁹⁰Y SIRT tumor dosimetry, while healthy liver absorbed dose values were comparable for all investigated imaging data. When no ⁹⁰Y PET/CT image data are available, the proposed scaled ^99mTc/⁹⁰Y SPECT/CT dosimetry method was found to be more appropriate for HCC tumor dosimetry than ⁹⁰Y BRS SPECT/CT based dosimetry.     

Preparation and biodistribution of a 99mTc tricarbonyl complex with deoxyglucose dithiocarbamate as a tumor imaging agent for SPECT

The deoxyglucose dithiocarbamate (DGDTC) was successfully labeled with the ^99mTc(CO)₃ core to provide the corresponding ^99mTc(CO)₃–DGDTC complex in good yields. The radiochemical purity of the ^99mTc(CO)₃–DGDTC complex was over 90%, as measured by high performance liquid chromatography (HPLC). The complex possessed good stability in saline at room temperature and in mouse plasma at 37 °C. Its partition coefficient result indicated that it was a hydrophilic complex. The electrophoresis results showed the complex was neutral. The biodistribution of ^99mTc(CO)₃–DGDTC in mice bearing S 180 tumor showed that the complex clearly accumulated in tumor, exhibiting high tumor/blood and tumor/muscle ratios and good tumor retention. Single photon emission computed tomography (SPECT) image studies showed there was a visible uptake in tumor sites, suggesting ^99mTc(CO)₃–DGDTC could be considered as a potential tumor imaging agent.     

Synthesis and evaluation of 99mTc–2-[(3-carboxy-1-oxopropyl)amino]-2-deoxy-d-glucose as a potential tumor imaging agent

The 2-[(3-carboxy-1-oxopropyl)amino]-2-deoxy-d-glucose (CPADG) was synthesized and radiolabeled with ^99mTcO₄⁻ to obtain the ^99mTc–CPADG complex in high yield. It was stable over 6 h in saline at room temperature and in serum at 37 °C. The partition coefficient and electrophoresis results indicated that the complex was hydrophilic and cationic. In vitro cell studies showed there was an increase in the uptake of ^99mTc–CPADG as a function of incubation time and ^99mTc–CPADG was possibly transported via the glucose transporters. The biodistribution of ^99mTc–CPADG in mice bearing S 180 tumor showed that the complex accumulated in the tumor with high uptake and good retention. The tumor/blood and tumor/muscle ratios increased with time and reached 1.91 and 5.05 at 4 h post-injection. Single photon emission computed tomography (SPECT) image studies showed there was an obvious accumulation in tumor sites, suggesting ^99mTc–CPADG would be a promising candidate for tumor imaging.     

Development of 99mTc-labeled asymmetric urea derivatives that target prostate-specific membrane antigen for single-photon emission computed tomography imaging

Prostate-specific membrane antigen (PSMA) is expressed strongly in prostate cancers and is, therefore, an attractive diagnostic and radioimmunotherapeutic target. In contrast to previous reports of PMSA-targeting ^99mTc-tricarbonyl complexes that are cationic or lack a charge, no anionic ^99mTc-tricarbonyl complexes have been reported. Notably, the hydrophilicity conferred by both cationic and anionic charges leads to rapid hepatobiliary clearance, whereas an anionic charge might better enhance renal clearance relative to a cationic charge. Therefore, an improvement in rapid clearance would be expected with either cationic or anionic charges, particularly anionic charges. In this study, we designed and synthesized a novel anionic ^99mTc-tricarbonyl complex ([^99mTc]TMCE) and evaluated its use as a single-photon emission computed tomography (SPECT) imaging probe for PSMA detection. Direct synthesis of [^99mTc]TMCE from dimethyl iminodiacetate, which contains both the asymmetric urea and succinimidyl moiety important for PSMA binding, was performed using our microwave-assisted one-pot procedure. The chelate formation was successfully achieved even though the precursor included a complicated bioactive moiety. The radiochemical yield of [^99mTc]TMCE was 12–17%, with a radiochemical purity greater than 98% after HPLC purification. [^99mTc]TMCE showed high affinity in vitro, with high accumulation in LNCaP tumors and low hepatic retention in biodistribution and SPECT/CT studies. These findings warrant further evaluation of [^99mTc]TMCE as an imaging agent and support the benefit of this strategy for the design of other PSMA imaging probes.     

Evaluation of 99mTc-CN5DG as a broad-spectrum SPECT probe for tumor imaging

Previously, we reported a [^99mTc(ǀ)]⁺ labeled d-glucoamine derivative (^99mTc-CN5DG) and evaluated it as a tumor imaging agent in mice bearing A549 tumor xenografts. In this paper, ^99mTc-CN5DG was further studied in U87 MG (human glioma cells), HCT-116 (human colon cancer cells), PANC-1 (human pancreatic cancer cells) and TE-1 (human esophageal cancer cells) tumor xenografts models to verify its potential application for imaging of different kinds of tumors. The biodistribution data showed that ^99mTc-CN5DG had a similar biodistribution pattern in four tumor models at 2 h post-injection with high accumulation in tumors and kidneys. The tumor/muscle ratios (from 4.08 ± 0.42 to 9.63 ± 3.53) and tumor/blood ratios (from 17.18 ± 7.40 to 53.17 ± 16.16) of ^99mTc-CN5DG in four tumor models were high. All four kinds of tumors could be clearly seen on their corresponding SPECT/CT images. Pharmacokinetic study in healthy CD-1 mice demonstrated that ^99mTc-CN5DG cleared fast from blood (2 min, 12.97 ± 0.88%ID/g; 60 min, 0.33 ± 0.06%ID/g) and the blood distribution, elimination half-life was 5.81 min and 21.16 min, respectively. No abnormality was observed through the abnormal toxicity study. All of the above results demonstrated that ^99mTc-CN5DG could be a broad-spectrum SPECT probe for tumor imaging and its further clinical application is warranted.     

Synthesis and biological evaluation of a novel 99mTc nitrido radiopharmaceutical with deoxyglucose dithiocarbamate,showing tumor uptake

The deoxyglucose dithiocarbamate (DGDTC) was synthesized and radiolabelled with [^99mTcN]²⁺ intermediate to form the ^99mTcN–DGDTC complex. The radiochemical purity of the ^99mTcN–DGDTC complex was over 90%, as measured by TLC and by HPLC, without any notable decomposition at room temperature over a period of 6 h. The partition coefficient and electrophoresis results indicated that this complex was hydrophilic and neutral. The biodistribution of ^99mTcN–DGDTC in mice bearing S 180 tumor showed that the complex accumulated in the tumor with high uptake and good retention. The tumor/blood and tumor/muscle ratios increased with time and reached 2.32 and 1.68 at 4 h post-injection, suggesting it would be a promising candidate for tumor imaging.     

99mTc-labeled monomeric and dimeric NGR peptides for SPECT imaging of CD13 receptor in tumor-bearing mice

CD13 receptor plays a critical role in tumor angiogenesis and metastasis. We therefore aimed to develop ^99mTc-labeled monomeric and dimeric NGR-containing peptides, namely, NGR1 and NGR2, for SPECT imaging of CD13 expression in HepG2 hepatoma xenografts. Both NGR-containing monomer and dimer were synthesized and labeled with ^99mTc. In vivo receptor specificity was demonstrated by successful blocking of tumor uptake of ^99mTc-NGR dimer in the presence of 20 mg/kg NGR2 peptide. Western blot and immunofluorescence staining confirmed the CD13 expression in HepG2 cells. The NGR dimer showed higher binding affinity and cell uptake in vitro than the NGR-containing monomer, presumably due to a multivalency effect. ^99mTc-Labeled monomeric and dimeric NGR-containing peptides were subjected to SPECT imaging and biodistribution studies. SPECT scans were performed in HepG2 tumor-bearing mice at 1, 4, 12, and 24 h post-injection of ~7.4 MBq tracers. The metabolism of tracers was determined in major organs at different time points after injection which demonstrated rapid, significant tumor uptake and slow tumor washout for both traces. Predominant clearance from renal and hepatic system was also observed in ^99mTc-NGR1 and ^99mTc-NGR2. In conclusion, monomeric and dimeric NGR peptide were developed and labeled with ^99mTc successfully, while the high integrin avidity and long retention in tumor make ^99mTc-NGR dimer a promising agent for tumor angiogenesis imaging.     

Metastatic melanoma imaging using a novel Tc-99m-labeled lactam-cyclized alpha-MSH peptide

The purpose of this study was to determine the metastatic melanoma imaging property of ^99mTc(EDDA)-HYNIC-Aoc-Nle-CycMSH_hex {hydrazinonicotinamide-8-aminooctanoic acid-Nle-c[Asp-His-DPhe-Arg-Trp-Lys]-CONH₂}. HYNIC-Aoc-Nle-CycMSH_hex was synthesized using fluorenylmethyloxy carbonyl (Fmoc) chemistry. The IC₅₀ value of HYNIC-Aoc-Nle-CycMSH_hex was 0.78?±?0.13?nM for B16/F10 melanoma cells. ^99mTc(EDDA)-HYNIC-Aoc-Nle-CycMSH_hex displayed significantly higher uptake (14.26?±?2.74 and 10.45?±?2.31%?ID/g) in B16/F10 metastatic melanoma-bearing lung than that in normal lung (0.90?±?0.15 and 0.53?±?0.14%?ID/g) at 2 and 4?h post-injection, respectively. B16/F10 pulmonary metastatic melanoma lesions were clearly visualized by SPECT/CT using ^99mTc(EDDA)-HYNIC-Aoc-Nle-CycMSH_hex as an imaging probe at 2?h post-injection, underscoring its potential as an imaging probe for metastatic melanoma detection.     

Synthesis of 99mTc-labeled 2-Mercaptobenzimidazole as a novel radiotracer to diagnose tumor hypoxia

Discovery of ^99mTc-labeled imidazole derivatives as a potential radiotracer for hypoxic tumor imaging is considered to be of great interest because of non-invasive detection capabilities. 2-Mercaptobenzimidazole (2-MBI) was successfully synthesized, characterized and radiolabeled with [^99mTc (CO)₃(H₂O)₃]⁺ intermediate to form ^99mTc-2-MBI complex with radiochemical purity of ≥95% yield as observed by instant-thin layer chromatography (ITLC) and radio-high performance liquid chromatography (radio-HPLC). The ^99mTc-2-MBI complex was observed to be stable in saline and serum with no noticeable decomposition at room temperature and 37 °C, respectively, over a time period of 24 h. Biodistribution results in Balb/c mice bearing S180 tumor show that ^99mTc-2-MBI highly internalized in tumor tissue, also possess preferably high tumor/muscle and tumor/blood ratios 4.14 ± 0.77 and 3.91 ± 0.63, respectively at 24 h incubation. Scintigraphic imaging study shows ^99mTc-2-MBI is visibly accumulated in hypoxic tumor tissue, suggesting it would be a promising radiotracer for early stage diagnosis of tumor hypoxia.