Asma Harun, Nathaniel Bendele, Mohammad Ibrahim Khalil, Isabella Vasquez, Jonathan Djuanda, Robert Posey, Md. Hasnat Rashid, Gordon F. Christopher, Ulrich Bickel, Viktor Gruev, Joshua Tropp, Paul F. Egan and Indrajit Srivastava*,
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引用次数: 0
摘要
荧光图像引导手术(FIGS)提供高空间分辨率和实时反馈,但受目前临床批准的荧光团的浅层组织穿透和自身荧光的限制。近红外(NIR)光谱,特别是NIR- i (700-900 nm)和NIR- ii (950-1700 nm),通过更深的组织穿透和改进的信噪比解决了这些限制。然而,手术条件下的生物屏障和不理想的光学性能阻碍了NIR-I/II纳米探针的临床转化。体内小鼠模型显示出了希望,但这些模型不能复制现实世界手术中遇到的复杂光学场景。现有的用于评估NIR-I/II成像系统的组织模拟模型是有用的,但在评估手术环境中的纳米探针时存在不足。这些幻影通常不能复制肿瘤微环境,限制了它们的预测评估。为了克服这些挑战,我们建议开发肿瘤模拟幻影模型(TMPs),该模型整合了肿瘤的关键特征,如可调节的肿瘤细胞密度、体内样纳米颗粒浓度、生物学相关因素(pH值、酶)、复制光吸收成分(血红蛋白)和光散射成分(脂肪内)。这些TMPs能够对nir - 1 /II纳米探针进行更多临床相关的评估,包括光学组织穿透谱、肿瘤边缘描绘和猪肺的体外胸外科手术。TMPs的成分可以进一步调制,以密切匹配体内和离体肿瘤的光学特征。此外,3D生物打印技术为在现实条件下筛选纳米探针提供了高通量平台。该方法将识别出具有优越手术效用的高性能NIR-I/II探针,弥合临床前发现和临床应用之间的差距,并确保结果超越传统的体内小鼠研究。
3D Tumor-Mimicking Phantom Models for Assessing NIR I/II Nanoparticles in Fluorescence-Guided Surgical Interventions
Fluorescence image-guided surgery (FIGS) offers high spatial resolution and real-time feedback but is limited by shallow tissue penetration and autofluorescence from current clinically approved fluorophores. The near-infrared (NIR) spectrum, specifically the NIR-I (700–900 nm) and NIR-II (950–1700 nm), addresses these limitations with deeper tissue penetration and improved signal-to-noise ratios. However, biological barriers and suboptimal optical performance under surgical conditions have hindered the clinical translation of NIR-I/II nanoprobes. In vivo mouse models have shown promise, but these models do not replicate the complex optical scenarios encountered during real-world surgeries. Existing tissue-mimicking phantoms used to evaluate NIR-I/II imaging systems are useful but fall short when assessing nanoprobes in surgical environments. These phantoms often fail to replicate the tumor microenvironment, limiting their predictive assessment. To overcome these challenges, we propose developing tumor-mimicking phantom models (TMPs) that integrate key tumor features, such as tunable tumor cell densities, in vivo-like nanoparticle concentrations, biologically relevant factors (pH, enzymes), replicate light absorption components (hemoglobin), and light scattering components (intralipid). These TMPs enable more clinically relevant assessments of NIR-I/II nanoprobes, including optical tissue penetration profiling, tumor margin delineation, and ex vivo thoracic surgery on porcine lungs. The components of TMPs can be further modulated to closely match the optical profiles of in vivo and ex vivo tumors. Additionally, 3D bioprinting technology facilitates a high-throughput platform for screening nanoprobes under realistic conditions. This approach will identify high-performing NIR-I/II probes with superior surgical utility, bridging the gap between preclinical findings and clinical applications, and ensuring results extend beyond traditional in vivo mouse studies.
期刊介绍:
ACS Nano, published monthly, serves as an international forum for comprehensive articles on nanoscience and nanotechnology research at the intersections of chemistry, biology, materials science, physics, and engineering. The journal fosters communication among scientists in these communities, facilitating collaboration, new research opportunities, and advancements through discoveries. ACS Nano covers synthesis, assembly, characterization, theory, and simulation of nanostructures, nanobiotechnology, nanofabrication, methods and tools for nanoscience and nanotechnology, and self- and directed-assembly. Alongside original research articles, it offers thorough reviews, perspectives on cutting-edge research, and discussions envisioning the future of nanoscience and nanotechnology.
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