AView: A Bedside Simulation Tool for Neurovascular Intervention

AView：神经血管干预的床边模拟工具

• 批准号: 8969365
• 负责人: HUI MENG
• 金额: $ 7.87万
• 依托单位: STATE UNIVERSITY OF NEW YORK AT BUFFALO
• 依托单位国家: 美国
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-09-01 至 2017-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8969365
• 关键词: Address; American; Aneurysm; Angiography; Biomedical Engineering; Blood Vessels; Center for Translational Science Activities; Cerebral Aneurysm; Characteristics; Clinical; Clinical Data; Clinical Research; Collaborations; Complication; Computer software; Data; Decision Making; Devices; Disease; Engineering; Feedback; Geometry; Grant; Guidelines; Health Care Costs; Health Personnel; Healthcare; Heart; Image; In Vitro; Institutes; Intervention; Libraries; Liquid substance; Location; Manuals; Measurement; Medical Imaging; Morphology; Neurosurgeon; Parents; Patient Care; Patients; Positioning Attribute; Procedures; Research; Research Personnel; Risk; Rupture; Ruptured Aneurysm; Seeds; Series; Slide; Solutions; Stents; Stroke; Surface; Testing; Three-Dimensional Image; Universities; Validation; Velocimetries; Vision; Work; base; clinical practice; density; hemodynamics; imaging Segmentation; improved; in vivo; operation; particle; prototype; public health relevance; research study; scaffold; simulation; tool; treatment planning; treatment site; virtual

 DESCRIPTION (provided by applicant): Cerebral aneurysms (CAs) are tricky to manage, since their rupture is deadly, rupture rate is low and treatment complication risk is significant. The new guidelines for CA management by the American Heart/Stroke Association suggest the clinicians: "consider morphological and hemodynamic characteristics of the aneurysm when discussing the risk of aneurysm rupture". However, morphometrics and hemodynamics require extensive engineering expertise to calculate. Currently there is no tool for clinicians to obtain such metrics. Through seamless collaboration between biomedical engineers from University's Clinical and Translational Research Center and neurosurgeons from the private healthcare provider Gates Vascular Institute in one building, we have developed the prototype of a clinical software platform, "AView", for rapid assessment of patient-specific CA hemodynamics and morphometrics at the bedside. We have further deployed this prototype to 8 clinical centers to test its technical feasibility. All participating clinicians enthusiastically embraced this ground-breaking tool. All of them underscored the urgent need of such a tool to be integrated into the day-to-day clinical workflow in CA management. They further indicated that routine clinical use of AView requires to have minimal manual operation and to provide maximal clinical benefits. Therefore, in this grant we would like to take a leap to transform AView from the current prototype into a bedside tool to improve healthcare. In Aim 1, we will automate image segmentation procedure. Specifically, a small number of seed spheres will be positioned on image slides, which will be automatically centered within the vessel as well as automatically resized. Furthermore, in this aim, we will implement a treatment planning module including coil density calculation and stent positioning measurement. Coil planning tool will guide users in choosing type and number of coils based on specific packing density, aneurysm volume and a built-in coil library. Stent planning tool will guide users in stent placement based on aneurysms morphology, vessel geometry and inflow jet. In Aim 2, we will validate the morphometric and hemodynamic calculation of AView using experiments from 5 patient-specific CAs. For morphometric validation, we will compare key morphometrics from AView against the results from standard software. For hemodynamic validation, we will validate flow calculation by in vitro and clinical data from the same 5 CAs. We will compare flow solutions against Particle Image Velocimetry data from CA phantoms, and flow-derived virtual angiography against patient angiography. Successful completion of this project will transform AView into an easy-to-use, high-impact, and well-validated bedside tool. We believe AView will revolutionize the way how neurosurgeons approach CA at the bedside. Our long-term vision of AView is to extend this tool to every participating healthcare provider, in order to facilitate on-site treatment decision- making and planning.

 描述(由申请人提供)：脑动脉瘤(CA)很难处理，因为它们的破裂是致命的，破裂率低，治疗并发症风险很大。美国心脏/卒中协会关于CA治疗的新指南建议临床医生：“在讨论动脉瘤破裂的风险时，应考虑动脉瘤的形态和血流动力学特征”。然而，形态计量学和血流动力学需要广泛的工程专业知识来计算。目前，临床医生还没有工具来获得这样的指标。通过来自大学临床和翻译研究中心的生物医学工程师和私人医疗保健提供商盖茨血管研究所的神经外科医生在一栋建筑中的无缝合作，我们开发了临床软件平台“AWIEW”的原型，用于在床边快速评估特定患者的CA血流动力学和形态测量。我们已经在8个临床中心进一步部署了这一原型，以测试其技术可行性。所有参与的临床医生都热情地接受了这一突破性的工具。所有这些都强调了在CA管理中将这种工具整合到日常临床工作流程中的迫切需要。他们进一步指出，aview的常规临床使用需要最少的手动操作，并提供最大的临床益处。因此，在这笔赠款中，我们想要跨出一步，将目前的原型转变为床边工具，以改善医疗保健。在目标1中，我们将自动执行图像分割过程。具体地说，少量的种子球将被放置在图像幻灯片上，这些图像将自动在血管内居中，并自动调整大小。此外，为了实现这一目标，我们将实现包括线圈密度计算和支架定位测量在内的治疗计划模块。弹簧圈规划工具将指导用户根据特定的填充密度、动脉瘤体积和内置弹簧圈资料库选择弹簧圈的类型和数量。支架规划工具将根据动脉瘤的形态、血管几何形状和流入射流指导用户放置支架。在目标2中，我们将使用来自5个患者特定CA的实验来验证Aview的形态计量学和血流动力学计算。对于形态测量验证，我们将比较来自Aview的关键形态测量与来自标准软件的结果。对于血流动力学验证，我们将验证体外流量计算和来自相同5个CA的临床数据。我们将比较流动解决方案与CA模体的粒子图像测速数据，以及流动衍生的虚拟血管成像与患者血管成像。该项目的成功完成将把AVIEW转变为一种易于使用、高效且经过充分验证的床边工具。我们相信，Aview将彻底改变神经外科医生在床边治疗CA的方式。我们对Aview的长期愿景是将这一工具扩展到每一家参与的医疗保健提供者，以促进现场治疗决策和规划。