A Perspective on Software Intelligence for Autonomous Transformations in Biomedical Data and Knowledge

IF 2.6 Q2 HEALTH POLICY & SERVICES

Learning Health Systems Pub Date : 2026-01-19 DOI:10.1002/lrh2.70063

Vivek Navale

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引用次数: 0

Abstract

Introduction

Persistent knowledge is essential for propagating the learning health system (LHS) cycle. Integral to the cycle are iterative transformations of data into knowledge. However, human efforts to undertake these transformations are increasingly challenged when dealing with larger data scales and complexities. Data sets within repositories and archives are often underutilized unless specifically requested for research programs. Specialized software algorithms (agents) can use existing knowledge for learning tasks, explore their environment, discover and create goals, and interact with humans.

Methods

This paper examines the potential role of software intelligence for autonomous transformations of data and knowledge. Agents can perform various goal-directed tasks. Multi-agent systems can be utilized for data collection, description, preparation, modeling, and knowledge-mining tasks. Knowledge representation, ontologies, semantic web standards, knowledge bases, and graphs can lead to a higher level of directed learning. Agents can develop reasoning abilities and self-generate goals by leveraging semantic relationships between various datasets.

Results

A conceptual framework for an intelligent biomedical platform (IBP) is proposed. The IBP comprises four layers: infrastructure (IS), user interface (UI), coordination system (CS), and data and knowledge (DK). It also integrates a network of multi-agent systems for clinical decision-making and knowledge-mining tasks. Intelligence in the platform results from the interaction of the IS, UI, CS, and DK agents. These agents can implement multiple inferential steps using the data and knowledge within accessible repositories. Large language models can be integrated with various knowledge resources and domain-specific databases, thereby improving the accuracy of results.

Conclusion

An IBP supported by a multi-agent system can enhance the autonomous transformation of data and knowledge. Including software intelligence within current repositories and archives enhances data reuse and the generation of new knowledge. With the addition of software reasoning capabilities in biomedical platforms, the LHS cycle can be efficiently propagated to aid in newer biomedical discoveries.

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生物医学数据和知识自主转换的软件智能展望

持续性知识对于学习型卫生系统（LHS）周期的传播至关重要。这个循环的组成部分是数据到知识的迭代转换。然而，当处理更大的数据规模和复杂性时，人类进行这些转换的努力日益受到挑战。除非研究项目特别要求，否则存储库和档案中的数据集往往未得到充分利用。专门的软件算法（代理）可以使用现有的知识来完成学习任务，探索环境，发现和创建目标，并与人类进行交互。方法本文探讨了软件智能在数据和知识自主转换中的潜在作用。代理可以执行各种目标导向的任务。多智能体系统可以用于数据收集、描述、准备、建模和知识挖掘任务。知识表示、本体、语义web标准、知识库和图形可以导致更高层次的定向学习。智能体可以通过利用各种数据集之间的语义关系来发展推理能力和自我生成目标。结果提出了智能生物医学平台的概念框架。IBP由IS （infrastructure）、UI （user interface）、CS （coordination system）和DK （data and knowledge）四层组成。它还集成了一个多代理系统网络，用于临床决策和知识挖掘任务。平台中的智能来自于IS、UI、CS和DK代理之间的交互。这些代理可以使用可访问存储库中的数据和知识实现多个推理步骤。大型语言模型可以与各种知识资源和特定领域的数据库集成，从而提高结果的准确性。结论多智能体系统支持的IBP可以增强数据和知识的自主转换。在当前存储库和存档中包含软件智能可以增强数据重用和新知识的生成。随着生物医学平台中软件推理能力的增加，LHS周期可以有效地传播，以帮助更新的生物医学发现。

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