Lee Seon Sook, Kim Hyunjin, Sohn Dae Kyung, Eom Joo Beom, Seo Young Seok, Yoon Hong Man, Choi Yongdoo
Research Institute, National Cancer Center, Goyang, Republic of Korea.
Center for Colorectal Cancer, National Cancer Center, Goyang, Republic of Korea.
Quant Imaging Med Surg. 2020 Mar;10(3):779-788. doi: 10.21037/qims.2020.02.24.
Accurate identification of tumor sites and boundaries is of paramount importance during minimally invasive surgery. Although laparoscopic resection is being increasingly and widely performed for early gastric and colorectal cancers, the detection of tumors located inside the stomach and intestine is difficult owing to the lack of tactile sensation. Here, we propose the application of an indocyanine green (ICG)-loaded alginate hydrogel system as a fluorescence surgical marker for precise laparoscopic operations.
A physical complex of ICG and human serum albumin (HSA) was mixed with sodium alginate to form an injectable hydrogel system. Calcium carbonate and D-gluconic acid (GA) were added to the gel to control its strength and gelation time, respectively. The optimal conditions for the preparation of injectable hydrogels were determined by analyzing the fluorescence spectra and sol-gel transition time of the prepared samples at various concentrations and compositions. Next, the aqueous solutions of ICG, ICG-HSA, and ICG-HSA-loaded alginate were subcutaneously injected into nude mice (three mice per group), and near-infrared (NIR) fluorescence images of the mice (λ =780 nm, λ =845 nm) were obtained at different points in time for 8 days. Then, fluorescence intensities at the injection sites, target-to-background ratio, and areas of ICG fluorescence were analyzed. Finally, the potential utility of ICG-HSA-loaded alginate hydrogel as a surgical marker was evaluated in a porcine model. The ICG-HSA-loaded alginate solution was injected into three sites in the submucosal space of the porcine stomach via a catheter. A fluorescent laparoscopic system was installed on the abdomen of the pig 3 days post-injection, and the fluorescence signal generated from the fluorescence surgical marker located inside the stomach was evaluated using the fluorescence laparoscope system (λ =785 nm, λ =805 nm).
The optimal concentration of ICG-HSA complex was determined to be 30 µM, and maximum fluorescence intensity of the complex was obtained at a 1:1 mole ratio of HSA to ICG. The subcutaneous injection of ICG or ICG-HSA solution in mice resulted in the rapid spread of the fluorescence signal around the injection site in 3 h, and a weak fluorescence was detected at the injection site 24 h post-injection. In contrast, the fluorescence detection time was effectively prolonged up to 96 h post-injection in the case of ICG-HSA-loaded alginate gel, while diffusion of the injected ICG from the injection site was effectively prevented. In the laparoscopic operation, injection sites of the hydrogel in porcine stomach could be accurately detected in real time even after 3 days.
This alginate hydrogel system may be potentially useful as an effective surgical marker in terms of accuracy and persistence for laparoscopic operation.
在微创手术中,准确识别肿瘤部位和边界至关重要。尽管腹腔镜切除术在早期胃癌和结直肠癌中的应用越来越广泛,但由于缺乏触觉,胃和肠道内肿瘤的检测仍很困难。在此,我们提出应用负载吲哚菁绿(ICG)的海藻酸水凝胶系统作为荧光手术标记物,用于精确的腹腔镜手术。
将ICG与人血清白蛋白(HSA)的物理复合物与海藻酸钠混合,形成可注射水凝胶系统。分别加入碳酸钙和D -葡萄糖酸(GA)来控制凝胶的强度和凝胶化时间。通过分析不同浓度和组成的制备样品的荧光光谱和溶胶 - 凝胶转变时间,确定制备可注射水凝胶的最佳条件。接下来,将ICG、ICG - HSA和负载ICG - HSA的海藻酸水溶液皮下注射到裸鼠体内(每组三只小鼠),并在8天内的不同时间点获取小鼠的近红外(NIR)荧光图像(λ = 780 nm,λ = 845 nm)。然后,分析注射部位的荧光强度、靶本比和ICG荧光面积。最后,在猪模型中评估负载ICG - HSA的海藻酸水凝胶作为手术标记物的潜在效用。通过导管将负载ICG - HSA的海藻酸溶液注射到猪胃黏膜下层的三个部位。注射后3天,在猪腹部安装荧光腹腔镜系统,使用荧光腹腔镜系统(λ = 785 nm,λ = 805 nm)评估胃内荧光手术标记物产生的荧光信号。
确定ICG - HSA复合物的最佳浓度为30 μM,在HSA与ICG的摩尔比为1:1时,复合物获得最大荧光强度。在小鼠皮下注射ICG或ICG - HSA溶液后,荧光信号在3小时内迅速在注射部位周围扩散,注射后24小时在注射部位检测到微弱荧光。相比之下,对于负载ICG - HSA的海藻酸凝胶,荧光检测时间有效延长至注射后96小时,同时有效防止了注射的ICG从注射部位扩散。在腹腔镜手术中,即使在3天后,也能实时准确检测到猪胃中水凝胶的注射部位。
就腹腔镜手术的准确性和持久性而言,这种海藻酸水凝胶系统可能作为一种有效的手术标记物具有潜在用途。
