Translational network neuroscience: Nine roadblocks and possible solutions.

IF 3.6 3区医学 Q2 NEUROSCIENCES

Network Neuroscience Pub Date : 2025-03-20 eCollection Date: 2025-01-01 DOI:10.1162/netn_a_00435

Lucius S Fekonja, Stephanie J Forkel, Dogu Baran Aydogan, Pantelis Lioumis, Alberto Cacciola, Carolin Weiß Lucas, Jacques-Donald Tournier, Francesco Vergani, Petra Ritter, Robert Schenk, Boshra Shams, Melina Julia Engelhardt, Thomas Picht

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Abstract

Translational network neuroscience aims to integrate advanced neuroimaging and data analysis techniques into clinical practice to better understand and treat neurological disorders. Despite the promise of technologies such as functional MRI and diffusion MRI combined with network analysis tools, the field faces several challenges that hinder its swift clinical translation. We have identified nine key roadblocks that impede this process: (a) theoretical and basic science foundations; (b) network construction, data interpretation, and validation; (c) MRI access, data variability, and protocol standardization; (d) data sharing; (e) computational resources and expertise; (f) interdisciplinary collaboration; (g) industry collaboration and commercialization; (h) operational efficiency, integration, and training; and (i) ethical and legal considerations. To address these challenges, we propose several possible solution strategies. By aligning scientific goals with clinical realities and establishing a sound ethical framework, translational network neuroscience can achieve meaningful advances in personalized medicine and ultimately improve patient care. We advocate for an interdisciplinary commitment to overcoming translational hurdles in network neuroscience and integrating advanced technologies into routine clinical practice.

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转化网络神经科学旨在将先进的神经成像和数据分析技术融入临床实践，以更好地了解和治疗神经系统疾病。尽管功能磁共振成像（Functional MRI）和弥散磁共振成像（Diffusion MRI）等技术与网络分析工具相结合前景广阔，但该领域仍面临着一些挑战，阻碍了其迅速转化为临床应用。我们确定了阻碍这一进程的九大障碍：(a) 理论和基础科学基础；(b) 网络构建、数据解读和验证；(c) MRI 访问、数据可变性和协议标准化；(d) 数据共享；(e) 计算资源和专业知识；(f) 跨学科合作；(g) 行业合作和商业化；(h) 运行效率、集成和培训；以及 (i) 道德和法律考虑。为了应对这些挑战，我们提出了几种可能的解决策略。通过将科学目标与临床现实相结合并建立健全的伦理框架，转化网络神经科学可以在个性化医疗方面取得有意义的进展，并最终改善患者护理。我们提倡跨学科合作，克服网络神经科学的转化障碍，将先进技术融入常规临床实践。

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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