Innovations in Shock Wave Lithotripsy Technology

冲击波碎石技术的创新

基本信息

批准号：
9039747
负责人：
PEI ZHONG
金额：
$ 65.92万
依托单位：
DUKE UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2015
资助国家：
美国
起止时间：
2015-09-01 至 2020-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9039747
关键词：
Acoustics American Animal Experiments Animal Model Area Award Biological Blood Vessels CHRM3 gene Calculi Cells Clinical Clinical Treatment Collaborations Coupling Development Devices Disease Educational process of instructing Electromagnetics Engineering Equipment Fracture Frequencies Gases Generations Goals Injury Instruction Interdisciplinary Study Kidney Calculi Laboratories Lasers Lithotripsy Manufacturer Name Mechanics Medical Methods Motion Patients Performance Physiologic pulse Procedures Progress Reports Research Risk Rupture Safety Science Shock Societies Surface System Technology Time Tissues Translational Research Universities Ureter Urologist Validation Water Width Work base design engineering design fundamental research improved in vitro testing innovation lens models and simulation next generation pressure professor prototype respiratory technology development transmission process treatment strategy urolithiasis

项目摘要

During the first period of the MERIT Award, we have completed most of the studies described in the four specific aims of the original application. We have designed a new acoustic lens that significantly improves the performance and safety of the Siemens lens based on in vitro tests and animal experiments. We have demonstrated the feasibility of a steerable and non-axisymmetric acoustic field in treating stones in the ureter or under the influence of respiratory motion. We have built a prototype electromagnetic annual ring shock wave generator and assessed the benefit of microsecond tandem pulse technology in stone comminution. We have investigated the effects of gas concentration in the coupling water and pulse repetition frequency (PRF) on the transmission of the lithotripter shock waves into the patient and resultant stone fragmentation. We have identified optimal treatment strategy to maximize stone comminution while minimizing tissue injury. We have further devised methods to mitigate the influence of cavitation bubbles along the beam path of the lithotripter in the coupling medium so that the treatment can be performed successfully at higher PRF (thus reducing treatment time) without increasing the risk of tissue injury. In addition, we have determined that average peak pressure is a critical parameter for stone comminution. This important finding provides the physical basis for understanding the benefit of broad focal width/low peak pressure lithotripters, such as the Dornier HM3 in clinical treatment. This extensive body of work has been carried out through synergistic collaborations between engineers, mathematicians, and urologists with the technical and equipment support of Siemens - one of the leading lithotripter manufacturers. In the extension application of this MERIT Award, we will continue fundamental research in the area of surface wave-induced stone fracture, cavitation-produced injury at cellular level and in small blood vessels. We will further expand on technology development in the area of steerable beam formation and wet coupling device that can be readily integrated in contemporary shock wave lithotripters. This new line of research will be carried out through engineering design innovation, multiphysics model simulation and experimental validations both in laboratory systems and in animal models. The overarching goal of this MERIT Award is to combine synergistically fundamental studies with technology innovations and translational research to improve the clinical performance and safety profile of contemporary shock wave lithotripters. RELEVANCE (See instructions); Shock wave lithotripsy (SWL) is a non-invasive procedure and remains to be the first-line therapy for the treatment of kidney stone disease. We will continue the fruitful multidisciplinary collaboration to combine fundamental research with technology innovation that can be translationed to the next-generation shock wave lithotripters. This work will significantly improve the quality of clinical treatment for urolithiasis patients worldwide.

在优异奖的第一阶段，我们已经完成了原始申请的四个具体目标中描述的大部分研究。根据体外测试和动物实验，我们设计了一种新型声学透镜，显着提高了西门子透镜的性能和安全性。我们已经证明了可操纵和非轴对称声场在治疗输尿管结石或呼吸运动影响下的可行性。我们构建了电磁年轮冲击波发生器原型，并评估了微秒串联脉冲技术在石料粉碎中的优势。我们研究了耦合水中的气体浓度和脉冲重复频率 (PRF) 对碎石机冲击波传输到患者体内以及由此产生的结石碎裂的影响。我们已经确定了最佳治疗策略，以最大限度地粉碎结石，同时最大限度地减少组织损伤。我们进一步设计了方法来减轻耦合介质中碎石机光束路径上空化气泡的影响，以便可以在更高的 PRF 下成功进行治疗（从而减少治疗时间），而不会增加组织损伤的风险。此外，我们还确定平均峰值压力是石料粉碎的关键参数。这一重要发现为了解宽焦宽/低峰值压力碎石机（例如 Dornier HM3）在临床治疗中的优势提供了物理基础。这项广泛的工作是通过工程师、数学家和泌尿科医生之间的协同合作以及西门子（领先的碎石机制造商之一）的技术和设备支持来完成的。在该优异奖的延伸应用中，我们将继续在表面波引起的结石破裂、细胞水平和小血管的空化损伤领域进行基础研究。我们将进一步扩大可操纵波束形成和湿耦合装置领域的技术开发，这些装置可以轻松集成到当代冲击波碎石机中。这一新的研究方向将通过工程设计创新、多物理场模型模拟以及实验室系统和动物模型中的实验验证来进行。该优异奖的总体目标是将基础研究与技术创新和转化研究相结合，以提高当代冲击波碎石机的临床表现和安全性。相关性（参见说明）；冲击波碎石术（SWL）是一种非侵入性手术，仍然是治疗肾结石疾病的一线疗法。我们将继续开展富有成效的多学科合作，将基础研究与技术创新相结合，并将其转化为下一代冲击波碎石机。这项工作将显着提高全球尿石症患者的临床治疗质量。