From gaps to guidelines: a process for providing guidance to bridge evidence gaps.

IF 2.9 4区医学 Q3 ENGINEERING, BIOMEDICAL

BioMedical Engineering OnLine Pub Date : 2025-05-03 DOI:10.1186/s12938-025-01385-6

Olga Yaroslavtseva, Judith Gargaro, Eleni M Patsakos, Aishwarya Nair, Robert Teasell, Mark T Bayley

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引用次数: 0

Abstract

Background: Despite the proliferation of clinical research that can be used to inform Clinical Practice Guidelines there remain many areas where the number and quality of research studies vary widely. Using the Canadian Clinical Practice Guideline for Moderate-to-Severe Traumatic Brain Injury (MOD-SEV TBI) as an example, there is a lack of robust research evidence, derived from randomized controlled trials, meta-analyses, and systematic reviews to inform the recommendations. Randomized controlled trials in this field often have limitations, such as smaller sample sizes and gender and racial disparities in enrollment, that reduce the level of evidence they can provide. Notably, evidence is often lacking in the priority areas identified by people with lived experience (PWLE) and guideline end-users.

Methods: The Canadian Clinical Practice Guideline for MOD-SEV TBI rehabilitation is a Living Guideline that implemented a robust and replicable process to mitigate these issues. This process includes: 1. Identification of Priorities by PWLE of MOD-SEV TBI and Guideline End-Users; 2. Involvement of Diverse Multidisciplinary Expert Panels, Including PWLE; 3. Compilation, Review and Evaluation of Published MOD-SEV TBI Evidence; 4. Identification of Gaps in the Published Literature; 5. Formulation of Recommendations, Rigorous Grading of Available Evidence and Formal Voting; 6. Creation of Knowledge Translation and Mobilization Tools and 7. Publication of the Updated Living Guideline.

Results: Since 2014-15, the Canadian TBI Living Guideline has implemented and refined this process to produce high-quality expert consensus-based recommendations and knowledge translation and mobilization tools across 21 comprehensive domains of TBI rehabilitation. There are 351 recommendations in the current version of the Canadian TBI Living Guideline; 68% of these are primarily consensus-based recommendations. Developing a comprehensive guideline in areas where research may not be present or strong ensures that the Guideline is comprehensive and addresses the priority needs of clinicians and PWLE.

Conclusions: The use of robust, transparent, and replicable evidence reviews and expert consensus building process produces clinical guidelines that are relevant and applicable even when empirical data are lacking or absent. This process of developing consensus-based recommendations can be used to develop guidelines in other content areas and populations facing similar challenges.

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从差距到指南：为弥合证据差距提供指导的过程。

背景：尽管可用于临床实践指南的临床研究数量激增，但仍有许多领域的研究数量和质量差异很大。以《加拿大中重度创伤性脑损伤临床实践指南》（MOD-SEV TBI）为例，缺乏来自随机对照试验、荟萃分析和系统评价的有力研究证据来为建议提供依据。这一领域的随机对照试验通常有局限性，比如样本量较小，在入组时存在性别和种族差异，这降低了它们能提供的证据水平。值得注意的是，在有生活经验的人（PWLE）和指南最终用户确定的优先领域往往缺乏证据。方法：加拿大MOD-SEV TBI康复临床实践指南是一个活生生的指南，它实施了一个强大的和可复制的过程来减轻这些问题。该过程包括：1；由MOD-SEV TBI的PWLE确定优先事项和指导最终用户；2. 包括PWLE在内的多学科专家小组的参与；3. MOD-SEV已发表TBI证据的编制、审查与评价4. 已发表文献中空白的识别5. 建议的制定，现有证据的严格分级和正式投票；6. 知识转化和动员工具的创造；公布最新生活指引。结果：自2014- 2015年以来，加拿大TBI生活指南已经实施并完善了这一过程，在21个TBI康复综合领域产生了基于专家共识的高质量建议和知识转化和动员工具。目前版本的加拿大脑外伤生活指南中有351条建议；其中68%主要是基于共识的建议。在研究可能不存在或研究力度不够的领域制定全面的指南，确保该指南是全面的，并解决临床医生和PWLE的优先需求。结论：使用稳健、透明和可复制的证据审查和专家共识建立过程，即使在缺乏或缺乏经验数据的情况下，也能产生相关和适用的临床指南。这一制定基于协商一致意见的建议的进程可用于在其他内容领域和面临类似挑战的人群中制定准则。

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

BioMedical Engineering OnLine 工程技术-工程：生物医学

CiteScore

6.70

自引率

2.60%

发文量

审稿时长

1 months

期刊介绍： BioMedical Engineering OnLine is an open access, peer-reviewed journal that is dedicated to publishing research in all areas of biomedical engineering. BioMedical Engineering OnLine is aimed at readers and authors throughout the world, with an interest in using tools of the physical and data sciences and techniques in engineering to understand and solve problems in the biological and medical sciences. Topical areas include, but are not limited to: Bioinformatics- Bioinstrumentation- Biomechanics- Biomedical Devices & Instrumentation- Biomedical Signal Processing- Healthcare Information Systems- Human Dynamics- Neural Engineering- Rehabilitation Engineering- Biomaterials- Biomedical Imaging & Image Processing- BioMEMS and On-Chip Devices- Bio-Micro/Nano Technologies- Biomolecular Engineering- Biosensors- Cardiovascular Systems Engineering- Cellular Engineering- Clinical Engineering- Computational Biology- Drug Delivery Technologies- Modeling Methodologies- Nanomaterials and Nanotechnology in Biomedicine- Respiratory Systems Engineering- Robotics in Medicine- Systems and Synthetic Biology- Systems Biology- Telemedicine/Smartphone Applications in Medicine- Therapeutic Systems, Devices and Technologies- Tissue Engineering