Large Language Models, scientific knowledge and factuality: A framework to streamline human expert evaluation

IF 4 2区医学 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Journal of Biomedical Informatics Pub Date : 2024-09-12 DOI:10.1016/j.jbi.2024.104724

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引用次数: 0

Abstract

Objective:

The paper introduces a framework for the evaluation of the encoding of factual scientific knowledge, designed to streamline the manual evaluation process typically conducted by domain experts. Inferring over and extracting information from Large Language Models (LLMs) trained on a large corpus of scientific literature can potentially define a step change in biomedical discovery, reducing the barriers for accessing and integrating existing medical evidence. This work explores the potential of LLMs for dialoguing with biomedical background knowledge, using the context of antibiotic discovery.

Methods:

The framework involves three evaluation steps, each assessing different aspects sequentially: fluency, prompt alignment, semantic coherence, factual knowledge, and specificity of the generated responses. By splitting these tasks between non-experts and experts, the framework reduces the effort required from the latter. The work provides a systematic assessment on the ability of eleven state-of-the-art LLMs, including ChatGPT, GPT-4 and Llama 2, in two prompting-based tasks: chemical compound definition generation and chemical compound–fungus relation determination.

Results:

Although recent models have improved in fluency, factual accuracy is still low and models are biased towards over-represented entities. The ability of LLMs to serve as biomedical knowledge bases is questioned, and the need for additional systematic evaluation frameworks is highlighted.

Conclusion:

While LLMs are currently not fit for purpose to be used as biomedical factual knowledge bases in a zero-shot setting, there is a promising emerging property in the direction of factuality as the models become domain specialised, scale up in size and level of human feedback.

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大型语言模型、科学知识和事实性：简化人类专家评估的框架

目的：本文介绍了一个评估事实科学知识编码的框架，旨在简化通常由领域专家进行的人工评估过程。通过大型科学文献语料库训练的大型语言模型（LLMs）推断和提取信息，有可能为生物医学发现带来阶跃式变化，减少获取和整合现有医学证据的障碍。方法：该框架包括三个评估步骤，每个步骤依次评估不同的方面：流畅性、提示一致性、语义连贯性、事实知识和生成回复的特异性。通过在非专家和专家之间拆分这些任务，该框架减少了后者所需的工作量。该研究对 ChatGPT、GPT-4 和 Llama 2 等 11 种最先进的 LLM 在两个基于提示的任务（化合物定义生成和化合物-真菌关系确定）中的能力进行了系统评估。结论：虽然 LLMs 目前还不适合作为零镜头环境下的生物医学事实知识库，但随着模型领域的专业化、规模的扩大和人类反馈水平的提高，在事实性方面出现了令人鼓舞的新特性。

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

Journal of Biomedical Informatics 医学-计算机：跨学科应用

CiteScore

8.90

自引率

6.70%

发文量

243

审稿时长

32 days

期刊介绍： The Journal of Biomedical Informatics reflects a commitment to high-quality original research papers, reviews, and commentaries in the area of biomedical informatics methodology. Although we publish articles motivated by applications in the biomedical sciences (for example, clinical medicine, health care, population health, and translational bioinformatics), the journal emphasizes reports of new methodologies and techniques that have general applicability and that form the basis for the evolving science of biomedical informatics. Articles on medical devices; evaluations of implemented systems (including clinical trials of information technologies); or papers that provide insight into a biological process, a specific disease, or treatment options would generally be more suitable for publication in other venues. Papers on applications of signal processing and image analysis are often more suitable for biomedical engineering journals or other informatics journals, although we do publish papers that emphasize the information management and knowledge representation/modeling issues that arise in the storage and use of biological signals and images. System descriptions are welcome if they illustrate and substantiate the underlying methodology that is the principal focus of the report and an effort is made to address the generalizability and/or range of application of that methodology. Note also that, given the international nature of JBI, papers that deal with specific languages other than English, or with country-specific health systems or approaches, are acceptable for JBI only if they offer generalizable lessons that are relevant to the broad JBI readership, regardless of their country, language, culture, or health system.