用于心肌梗死后生物材料注射治疗的热响应水凝胶与机器人系统耦合设计
Design of a Coupled Thermoresponsive Hydrogel and Robotic System for Postinfarct Biomaterial Injection Therapy.
作者信息
Zhu Yang, Wood Nathan A, Fok Kevin, Yoshizumi Tomo, Park Dae Woo, Jiang Hongbin, Schwartzman David S, Zenati Marco A, Uchibori Takafumi, Wagner William R, Riviere Cameron N
机构信息
McGowan Institute for Regenerative Medicine, University of Pittsburgh, Pittsburgh, Pennsylvania; Department of Bioengineering, University of Pittsburgh, Pittsburgh, Pennsylvania.
The Robotics Institute, Carnegie Mellon University, Pittsburgh, Pennsylvania.
出版信息
Ann Thorac Surg. 2016 Sep;102(3):780-786. doi: 10.1016/j.athoracsur.2016.02.082. Epub 2016 May 4.
BACKGROUND
In preclinical testing, ventricular wall injection of hydrogels has been shown to be effective in modulating ventricular remodeling and preserving cardiac function. For some approaches, early-stage clinical trials are under way. The hydrogel delivery method varies, with minimally invasive approaches being preferred. Endocardial injections carry a risk of hydrogel regurgitation into the circulation, and precise injection patterning is a challenge. An epicardial approach with a thermally gelling hydrogel through the subxiphoid pathway overcomes these disadvantages.
METHODS
A relatively stiff, thermally responsive, injectable hydrogel based on N-isopropylacrylamide and N-vinylpyrrolidone (VP gel) was synthesized and characterized. VP gel thermal behavior was tuned to couple with a transepicardial injection robot, incorporating a cooling feature to achieve injectability. Ventricular wall injections of the optimized VP gel have been performed ex vivo and on beating porcine hearts.
RESULTS
Thermal transition temperature, viscosity, and gelling time for the VP gel were manipulated by altering N-vinylpyrrolidone content. The target parameters for cooling in the robotic system were chosen by thermal modeling to support smooth, repeated injections on an ex vivo heart. Injections at predefined locations and depth were confirmed in an infarcted porcine model.
CONCLUSIONS
A coupled thermoresponsive hydrogel and robotic injection system incorporating a temperature-controlled injectate line was capable of targeted injections and amenable to use with a subxiphoid transepicardial approach for hydrogel injection after myocardial infarction. The confirmation of precise location and depth injections would facilitate a patient-specific planning strategy to optimize injection patterning to maximize the mechanical benefits of hydrogel placement.
背景
在临床前测试中,已证明在心室内壁注射水凝胶可有效调节心室重构并维持心脏功能。对于某些方法,早期临床试验正在进行中。水凝胶的递送方法各不相同,其中微创方法更受青睐。心内膜注射存在水凝胶反流进入循环系统的风险,并且精确的注射模式是一项挑战。通过剑突下途径使用热凝胶化水凝胶的心外膜方法克服了这些缺点。
方法
合成并表征了一种基于N-异丙基丙烯酰胺和N-乙烯基吡咯烷酮的相对坚硬、热响应性、可注射水凝胶(VP凝胶)。对VP凝胶的热行为进行了调整,使其与经心外膜注射机器人相匹配,该机器人具有冷却功能以实现可注射性。已在离体和跳动的猪心脏上进行了优化后的VP凝胶的心室内壁注射。
结果
通过改变N-乙烯基吡咯烷酮的含量来控制VP凝胶的热转变温度、粘度和胶凝时间。通过热模型选择机器人系统中的冷却目标参数,以支持在离体心脏上进行平滑、重复的注射。在梗死猪模型中证实了在预定位置和深度的注射。
结论
一种结合了温度控制注射管路的热响应性水凝胶和机器人注射系统能够进行靶向注射,并且适用于在心肌梗死后通过剑突下经心外膜途径进行水凝胶注射。精确位置和深度注射的确认将有助于制定针对患者的规划策略,以优化注射模式,从而最大限度地提高水凝胶放置的机械益处。
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