Evaluation of Suprachoroidal Injection in Cadaveric and Preclinical Models.

IF 2.6 3区医学 Q2 OPHTHALMOLOGY

Translational Vision Science & Technology Pub Date : 2025-03-03 DOI:10.1167/tvst.14.3.20

Mark Hedgeland, Sergio Camacho Gonzalez, Dimitrios Stampoulis, Vivian Lee, Kate Powell, Yubin Qiu, Robert Hodge, Greg Bell, Amanda Fago, Rebecca Atkinson-Dell, Nadya Choti, Kirsten Stoner

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引用次数: 0

Abstract

Purpose: The suprachoroidal space (SCS) is a new route for delivering therapeutics to the posterior eye. Reliably reaching the SCS is difficult in humans and animal models and necessitates thorough validation of drug delivery techniques. This study quantified SCS coverage in human cadaveric eyes using micro-computed tomography (μCT) and developed injectors optimized for preclinical animal anatomy resulting in reliable SCS access.

Methods: Dynamic μCT captured volumetric images during a 100 µL SCS injection in 10 cadaveric human eyes from five donors. Quantitative measurements of injection coverage, thickness, distribution, and center of volume were calculated. To improve preclinical SCS delivery, our novel TS-Micro injector was scaled to accommodate non-human primate (NHP) anatomy. Devices were tested in vivo (30 total injections, 14 animals) where delivery success was evaluated via direct visualization, and intraoperative imaging.

Results: Delivery to the SCS was successful in 100% of uncompromised human cadaver eyes (80% of all eyes). Injections of 100 µL in human SCS covered 33.3% ± 5.9%. Four-dimensional μCT showed that infusate initially spreads circumferentially from the injection point then posteriorly. Delivery to NHP eyes was successful in 95% of procedures resulting in coverage consistent to human cadaveric testing.

Conclusions: Results provide the first quantifiable measurement of SCS injection spread in human anatomy with validation of suprachoroidal drug delivery in the NHP that mirrors coverage in human.

Translational relevance: Cell and gene therapies require precise delivery for therapeutic efficacy, necessitating quantification of delivery in preclinical and human anatomy, as inaccurate delivery impacts efficacy of drug candidates and confounds toxicology/dose range studies.

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脉络膜上注射在尸体和临床前模型中的评价。

目的：脉络膜上间隙（SCS）是向后眼输送治疗药物的新途径。在人类和动物模型中，可靠地到达SCS是困难的，需要彻底验证给药技术。本研究利用微计算机断层扫描（μCT）量化了人尸体眼睛中SCS的覆盖范围，并开发了针对临床前动物解剖优化的注射器，从而实现了可靠的SCS接入。方法：动态μCT采集5个供体10只人尸体眼100µL SCS注射时的体积图像。定量测量注射覆盖，厚度，分布，和中心的体积计算。为了改善临床前SCS的输送，我们的新型TS-Micro注射器被缩放以适应非人灵长类动物（NHP）的解剖结构。装置在体内进行了测试（总共30次注射，14只动物），通过直接可视化和术中成像来评估输送成功。结果：100%未受损的人尸体眼睛（占所有眼睛的80%）成功递送到SCS。注射100µL的人SCS占33.3%±5.9%。四维μCT显示，注射点开始呈周向扩散，后向扩散。在95%的手术中，向NHP眼睛的输送是成功的，其覆盖范围与人体尸体检测一致。结论：研究结果首次提供了人体解剖学中SCS注射扩散的可量化测量，并验证了NHP的脉络膜上药物传递反映了人类的覆盖范围。翻译相关性：细胞和基因治疗需要精确的递送以获得治疗效果，因此需要在临床前和人体解剖学中定量递送，因为不准确的递送会影响候选药物的疗效，并混淆毒理学/剂量范围研究。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Translational Vision Science & Technology Engineering-Biomedical Engineering

CiteScore

5.70

自引率

3.30%

发文量

346

审稿时长

25 weeks

期刊介绍： Translational Vision Science & Technology (TVST), an official journal of the Association for Research in Vision and Ophthalmology (ARVO), an international organization whose purpose is to advance research worldwide into understanding the visual system and preventing, treating and curing its disorders, is an online, open access, peer-reviewed journal emphasizing multidisciplinary research that bridges the gap between basic research and clinical care. A highly qualified and diverse group of Associate Editors and Editorial Board Members is led by Editor-in-Chief Marco Zarbin, MD, PhD, FARVO. The journal covers a broad spectrum of work, including but not limited to: Applications of stem cell technology for regenerative medicine, Development of new animal models of human diseases, Tissue bioengineering, Chemical engineering to improve virus-based gene delivery, Nanotechnology for drug delivery, Design and synthesis of artificial extracellular matrices, Development of a true microsurgical operating environment, Refining data analysis algorithms to improve in vivo imaging technology, Results of Phase 1 clinical trials, Reverse translational ("bedside to bench") research. TVST seeks manuscripts from scientists and clinicians with diverse backgrounds ranging from basic chemistry to ophthalmic surgery that will advance or change the way we understand and/or treat vision-threatening diseases. TVST encourages the use of color, multimedia, hyperlinks, program code and other digital enhancements.