Ex Vivo Human Tissue Functions as a Testing Platform for the Evaluation of a Nerve-Specific Fluorophore.

IF 3 4区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Molecular Imaging and Biology Pub Date : 2025-02-01 Epub Date: 2024-12-10 DOI:10.1007/s11307-024-01968-0

Logan M Bateman, Samuel S Streeter, Kendra A Hebert, Dylan J Parker, Kaye Obando, Kiara Sherlin Salas Moreno, George J Zanazzi, Connor W Barth, Lei G Wang, Summer L Gibbs, Eric R Henderson

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引用次数: 0

Abstract

Significance: Selecting a nerve-specific lead fluorescent agent for translation in fluorescence-guided surgery is time-consuming and expensive. Preclinical fluorescent agent studies rely primarily on animal models, which are a critical component of preclinical testing, but these models may not predict fluorophore performance in human tissues.

Aim: The primary aim of this study was to evaluate and compare two preclinical models to test tissue-specific fluorophores based on discarded human tissues. The secondary aim was to use these models to determine the ability of a molecularly targeted fluorophore, LGW16-03, to label ex vivo human nerve tissues.

Approach: Patients undergoing standard-of-care transtibial or transfemoral amputation were consented and randomized to topical or systemic administration of LGW16-03 following amputation. After probe administration, nerves and background tissues were surgically resected and imaged to determine nerve fluorescence signal-to-background tissue ratio (SBR) and signal-to-noise ratio (SNR) metrics. Analysis of variance (ANOVA) determined statistical differences in metric means between administration cohorts and background tissue groups. Receiver operating characteristic (ROC) curve-derived statistics quantified the discriminatory performance of LGW16-03 fluorescence for labeling nerve tissues.

Results: Tissue samples from 18 patients were analyzed. Mean nerve-to-adipose SBR was greater than nerve-to-muscle SBR (p = 0.001), but mean nerve-to-adipose SNR was not statistically different from mean nerve-to-muscle SNR (p = 0.069). Neither SBR nor SNR means were statistically different between fluorophore administration cohorts (p ≥ 0.448). When administration cohorts were combined, nerve-to-adipose SBR was greater than nerve-to-muscle SBR (mean ± standard deviation; 4.2 ± 2.9 vs. 1.8 ± 1.9; p < 0.001), but SNRs for nerve-to-adipose and nerve-to-muscle were not significantly different (5.1 ± 4.0 vs. 3.1 ± 3.4; p = 0.055). ROC curve-derived statistics to quantify LGW16-03 nerve labeling performance varied widely between patients, with sensitivities and specificities ranging from 0.2-99.9% and 0.4-100.0%.

Conclusion: Systemic and topical administration of LGW16-03 yielded similar fluorescence labeling of nerve tissues. Both administration approaches provided nerve-specific contrast similar to that observed in preclinical animal models. Fluorescence contrast was generally higher for nerve-to-adipose versus nerve-to-muscle. Ex vivo human tissue models provide safe evaluation of fluorophores in the preclinical phase and can aid in the selection of lead agents prior to first-in-human trials.

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离体人体组织功能作为评估神经特异性荧光团的测试平台。

意义：在荧光引导手术中，选择一种神经特异性的先导荧光剂进行转译既耗时又昂贵。临床前荧光剂研究主要依赖于动物模型，这是临床前测试的关键组成部分，但这些模型可能无法预测人体组织中的荧光团性能。目的：本研究的主要目的是评估和比较两种临床前模型，以测试基于废弃人体组织的组织特异性荧光团。第二个目的是利用这些模型来确定分子靶向荧光团LGW16-03标记离体人类神经组织的能力。方法：接受标准治疗的经胫骨或经股骨截肢的患者被同意并随机分配到局部或全身给药LGW16-03。在给药后，手术切除神经和背景组织并成像以确定神经荧光信号与背景组织比（SBR）和信噪比（SNR）指标。方差分析（ANOVA）确定了给药组和背景组织组之间度量方法的统计差异。受试者工作特征（ROC）曲线统计量化了LGW16-03荧光标记神经组织的区分性能。结果：对18例患者的组织样本进行了分析。平均神经到脂肪的SBR大于神经到肌肉的SBR (p = 0.001)，但平均神经到脂肪的信噪比与平均神经到肌肉的信噪比无统计学差异（p = 0.069）。SBR和SNR均值在给药组之间均无统计学差异（p≥0.448）。当给药队列合并时，神经到脂肪的SBR大于神经到肌肉的SBR(平均值±标准差；4.2±2.9 vs. 1.8±1.9；结论：全身和局部给药LGW16-03对神经组织产生相似的荧光标记。两种给药方法都提供了类似于临床前动物模型中观察到的神经特异性对比。神经到脂肪的荧光对比通常高于神经到肌肉的荧光对比。离体人体组织模型可在临床前阶段对荧光团进行安全评估，并有助于在首次人体试验之前选择先导药物。

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来源期刊

Molecular Imaging and Biology 医学-核医学

CiteScore

6.90

自引率

3.20%

发文量

审稿时长

3 months

期刊介绍： Molecular Imaging and Biology (MIB) invites original contributions (research articles, review articles, commentaries, etc.) on the utilization of molecular imaging (i.e., nuclear imaging, optical imaging, autoradiography and pathology, MRI, MPI, ultrasound imaging, radiomics/genomics etc.) to investigate questions related to biology and health. The objective of MIB is to provide a forum to the discovery of molecular mechanisms of disease through the use of imaging techniques. We aim to investigate the biological nature of disease in patients and establish new molecular imaging diagnostic and therapy procedures. Some areas that are covered are: Preclinical and clinical imaging of macromolecular targets (e.g., genes, receptors, enzymes) involved in significant biological processes. The design, characterization, and study of new molecular imaging probes and contrast agents for the functional interrogation of macromolecular targets. Development and evaluation of imaging systems including instrumentation, image reconstruction algorithms, image analysis, and display. Development of molecular assay approaches leading to quantification of the biological information obtained in molecular imaging. Study of in vivo animal models of disease for the development of new molecular diagnostics and therapeutics. Extension of in vitro and in vivo discoveries using disease models, into well designed clinical research investigations. Clinical molecular imaging involving clinical investigations, clinical trials and medical management or cost-effectiveness studies.