Computational Analysis of Noninvasive Ventilation

无创通气的计算分析

• 批准号: 7320351
• 负责人: JOHN R HOTCHKISS
• 金额: $ 41.55万
• 依托单位: UNIVERSITY OF PITTSBURGH AT PITTSBURGH
• 依托单位国家: 美国
• 财政年份: 2007
• 资助国家: 美国
• 起止时间: 2007-07-20 至 2012-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7320351
• 关键词: Acute; Address; Algorithms; Behavior; Breathing; Calibration; Characteristics; Classification; Clinical; Clinical Trials; Complex; Computer Analysis; Computer Simulation; Computer software; Conflict (Psychology); Data; Databases; Effectiveness of Interventions; Emergency Care; Environmental air flow; Evaluation; Family; Feedback; Foundations; Gases; Goals; Home environment; Homeostasis; Individual; Injury; Intervention; Investigation; Laboratories; Lead; Libraries; Link; Lung; Measurement; Mechanical ventilation; Modeling; Monitor; Obstructive Sleep Apnea; Patient Monitoring; Patients; Pattern; Population; Process; Pulmonary Emphysema; Range; Research; Resistance; Respiratory Failure; Respiratory System; Structure; Techniques; Testing; Time; Validation; Ventilator; Work; electric impedance; human data; improved; mathematical model; pressure; respiratory; simulation; software development; tool

DESCRIPTION (provided by applicant): Despite its recognition as a lifesaving intervention and cornerstone of modern intensive and emergency care, mechanical ventilation can be both uncomfortable and injurious. Complex interactions between patient characteristics and the manner in which the ventilator applies flow and pressure determine the level and adequacy of support, the degree of patient comfort, and the potential for injury. Patient: ventilator interaction is a complex and dynamic process, fraught with feedback loops and adaptation. This complexity is of greatest importance in the setting of pressure support noninvasive ventilation (PSNIV), an increasingly common approach to supporting individuals with respiratory failure. There is not at present a rigorous conceptual foundation for optimizing the application of PSNIV. We will develop both a mathematically rigorous conceptual framework and a suite of practical tools for analyzing, monitoring, and optimizing the application of pressure support noninvasive ventilation by accomplishing 4 specific aims. 1) Specific Aim One: Develop, calibrate, and validate practical mathematical models and tools for the real- time analysis of pressure support noninvasive ventilation; 2) Specific Aim Two: Use human data to construct libraries of patient impedance (lung "stiffness" and resistance) characteristics and patterns of respiratory effort during assisted breathing and systematically investigate interactions between model complexity and the accuracy and robustness of model predictions; 3) Specific Aim Three: Apply contemporary mathematical techniques to identify approaches for applying PSNIV that are anticipated to improve the likelihood of adequate support in specific populations; 4) Specific Aim Four: Develop automated, noninvasive tools to a) identify airway opening flow- and pressure profiles indicating potential patient: ventilator conflict and b) objectively classify patient breathing patterns. These tools will be developed from "first principles," with rigorous mathematical and laboratory analyses and optimization that will be tightly linked to clinical calibration, evaluation, and validation. This work will ultimately help us to better manage patients who are treated with noninvasive ventilation, whether for an acute illness (such as an exacerbation of emphysema), or at home (as in the case of obstructive sleep apnea).

描述（由申请人提供）：尽管机械通气被公认为是一种救生干预措施，也是现代重症和急诊护理的基石，但它可能既不舒服又有害。患者特征与呼吸机施加流量和压力的方式之间的复杂相互作用决定了支持的水平和充分性、患者的舒适度以及受伤的可能性。患者与呼吸机的交互是一个复杂的动态过程，充满了反馈回路和适应。这种复杂性在压力支持无创通气（PSNIV）的设置中最为重要，PSNIV是支持呼吸衰竭患者的一种越来越常见的方法。目前还没有一个严格的概念基础，优化PSNIV的应用。我们将开发一个数学上严格的概念框架和一套实用的工具，用于分析，监测和优化压力支持无创通气的应用，实现4个具体目标。 1)具体目标一：开发、校准和验证用于压力支持无创通气的真实的实时分析的实用数学模型和工具; 2)具体目标二：使用人体数据构建患者阻抗（肺“硬度”和阻力）特征库和辅助呼吸期间呼吸努力模式，并系统地研究模型复杂性与模型预测准确性和鲁棒性之间的相互作用; 3)具体目标三：应用现代数学技术，确定应用PSNIV的方法，预计这些方法将提高特定人群获得充分支持的可能性; 4)具体目标四：开发自动化、无创工具，以a）识别气道开放流量和压力曲线，表明潜在的患者：呼吸机冲突，以及B）客观地对患者呼吸模式进行分类。 这些工具将从“第一原理”开发，具有严格的数学和实验室分析和优化，将与临床校准，评估和验证紧密联系。这项工作最终将帮助我们更好地管理接受无创通气治疗的患者，无论是急性疾病（如肺气肿加重）还是在家（如阻塞性睡眠呼吸暂停）。