Evolution, applications and prospects of virtual standardized patient technology in educational contexts

doi:10.3760/cma.j.cn115259-20250523-00582

Abstract

Abstract: Virtual standardized patient (VSP), which result from the advanced integration of artificial intelligence with simulation-based medical education, are catalyzing a shift in medical education towards a data-driven paradigm. This paper provides a systematic analysis of the technological advancements in VSP, highlighting their fundamental distinctions from traditional standardized patients. It further examines the divergent developmental trajectories in technical architecture and functional orientation between China and other countries. Domestically, there is an emphasis on intelligent scoring systems for assessment and evaluation, whereas internationally, the focus is on process-oriented multimodal immersive interaction. VSP presents notable benefits in terms of cost-effectiveness, uniformity in instruction, and adaptability in various scenarios. However, they also encounter practical challenges, such as limitations in replicating non-verbal communication, potential for content distortion, and the lack of standardized evaluation criteria. Future advancements in VSP development should focus on technological integration, progressing from multimodal interactions to physiological closed-loop systems. Additionally, there is a need for standardization to move from disparate practices to a cohesive assessment framework, and for security governance to transition from passive protection measures to proactive management strategies. This study seeks to serve as a foundational reference for the localized development and implementation of VSP, as well as for the advancement of intelligent methodologies in medical education.

Key words: Patient simulation, Virtual standardized patients, Medical simulation education, Virtual reality, Technological paradigms, Research progress

CLC Number:

Liu Ying, Yuan Qing, Cheng Linjie, Yin Wanyi, Jiang Zhehan. Evolution, applications and prospects of virtual standardized patient technology in educational contexts[J]. Chinese Journal of Medical Education, 2026, 46(5): 331-336.

References

[1] 孙雨哲, 王宪娥, 侯建霞. 虚拟标准化病人在医学教育中的应用与研究进展[J].中华医学教育杂志,2024,44(4):294-298. DOI:10.3760/cma.j.cn115259-20230414-00390.
[2] 喻佳龙, 李月, 秦建星, 等. 虚拟标准化病人有效性评估研究进展[J].中华医学教育杂志,2026,46(1):15-20. DOI:10.3760/cma.j.cn115259-20240722-00770.
[3] Hamilton A, Molzahn A, McLemore K. The evolution from standardized to virtual patients in medical education[J].Cureus, 2024,16(10):e71224. DOI:10.7759/cureus.71224.
[4] Gray M, Baird A, Sawyer T, et al.Increasing realism and variety of virtual patient dialogues for prenatal counseling education through a novel application of ChatGPT: exploratory observational study[J].JMIR Med Educ, 2024,10:e50705. DOI:10.2196/50705.
[5] 李翔, 梁杰, 陈晓云, 等. 虚拟仿真实验教学平台在病史采集教学中的应用[J].医学研究与教育,2025,42(3):74-80. DOI:10.3969/j.issn.1674-490X.2025.03.010.
[6] 汪国栋, 李月, 秦建星, 等. 虚拟标准化病人在精神医学教学中的应用与展望[J].神经疾病与精神卫生,2025,25(1):68-72. DOI:10.3969/j.issn.1009-6574.2025.01.010.
[7] Weisman D, Sugarman A, Huang YM, et al.Development of a GPT-4-powered virtual simulated patient and communication training platform for medical students to practice discussing abnormal mammogram results with patients: multiphase study[J].JMIR Form Res, 2025,9:e65670. DOI:10.2196/65670.
[8] Wang Y, Chen Y, Sheng J.Assessing ChatGPT as a medical consultation assistant for chronic hepatitis B: cross-language study of English and Chinese[J].JMIR Med Inform, 2024,12:e56426. DOI:10.2196/56426.
[9] Raheel A.Emotion analysis and recognition in 3D space using classifier-dependent feature selection in response to tactile enhanced audio-visual content using EEG[J].Comput Biol Med, 2024,179:108807. DOI:10.1016/j.compbiomed.2024.108807.
[10] Zhou Q. HGLER: a hierarchical heterogeneous graph networks for enhanced multimodal emotion recognition in conversations[J].PLoS One, 2025,20(9):e0330632. DOI:10.1371/journal.pone.0330632.
[11] Kapgate DD.Application of hybrid SSVEP + P300 brain computer interface to control avatar movement in mobile virtual reality gaming environment[J].Behav Brain Res, 2024,472:115154. DOI:10.1016/j.bbr.2024.115154.
[12] Liu Y, Shi C, Wu L, et al. Development and validation of a large language model-based system for medical history-taking training: prospective multicase study on evaluation stability, human-AI consistency, and transparency[J].JMIR Med Educ, 2025,11:e73419. DOI:10.2196/73419.
[13] Du J, Zhu X, Wang J, et al.History-taking level and its influencing factors among nursing undergraduates based on the virtual standardized patient testing results: cross sectional study[J].Nurse Educ Today, 2022,111:105312. DOI:10.1016/j.nedt.2022.105312.
[14] Sonoda Y, Kurokawa R, Hagiwara A, et al. Structured clinical reasoning prompt enhances LLM′s diagnostic capabilities in diagnosis please quiz cases[J].Jpn J Radiol, 2025,43(4):586-592. DOI:10.1007/s11604-024-01712-2.
[15] Zhang X, Zeng D, Wang X, et al.Analysis of virtual standardized patients for assessing clinical fundamental skills of medical students: a prospective study[J].BMC Med Educ, 2024,24(1):981. DOI:10.1186/s12909-024-05982-2.
[16] 陈娜平, 唐陆禛, 黄贤生, 等. 基于ChatGPT-4的虚拟标准化病人应用研究[J].中华医学教育杂志,2025,45(1):44-49. DOI:10.3760/cma.j.cn115259-20240307-00225.
[17] Yang H, Xiao X, Wu X, et al. Virtual standardized patients versus traditional academic training for improving clinical competence among traditional Chinese medicine students: prospective randomized controlled trial[J].J Med Internet Res, 2023,25:e43763. DOI:10.2196/43763.
[18] Mishra C, Verdonschot R, Hagoort P, et al. Real-time emotion generation in human-robot dialogue using large language models[J].Front Robot AI, 2023,10:1271610. DOI:10.3389/frobt.2023.1271610.
[19] Reger GM, Norr AM, Gramlich MA, et al. Virtual standardized patients for mental health education[J].Curr Psychiatry Rep, 2021,23(9):57. DOI:10.1007/s11920-021-01273-5.
[20] Maicher KR, Zimmerman L, Wilcox B, et al. Using virtual standardized patients to accurately assess information gathering skills in medical students[J].Med Teach, 2019,41(9):1053-1059. DOI:10.1080/0142159X.2019.1616683.
[21] Reger GM, Norr AM, Rizzo AS, et al. Virtual standardized patients vs academic training for learning motivational interviewing skills in the US department of veterans affairs and the US military: a randomized trial[J].JAMA Netw Open, 2020,3(10):e2017348. DOI:10.1001/jamanetworkopen.2020.17348.
[22] 赵玉, 郭忠. 虚拟标准化病人在机能实验教学中的应用[J].基础医学教育,2024,26(4):335-339. DOI:10.13754/j.issn2095-1450.2024.04.14.
[23] Jensen R, Musaeus P, Pedersen K. Virtual patients in undergraduate psychiatry education: a systematic review and synthesis[J].Adv Health Sci Educ Theory Pract, 2024,29(1):329-347. DOI:10.1007/s10459-023-10247-6.
[24] Bond WF, Mischler MJ, Lynch TJ, et al. The use of virtual standardized patients for practice in high value care[J].Simul Healthc, 2023,18(3):147-154. DOI:10.1097/SIH.0000000000000659.
[25] 吴丽, 孙卫斌, 聂蓉蓉, 等. 虚拟仿真标准化病人软件系统在口腔住院医师OSCE考核中的应用[J].口腔材料器械杂志,2023,32(4):290-294. DOI:10.11752/j.kqcl.2023.04.12.
[26] Casas L, Hannah S, Mitchell K. HoloJig:interactive spoken prompt specified generative AI environments[J].IEEE Comput Graph Appl, 2025,45(2):69-77. DOI:10.1109/MCG.2025.3553780.
[27] Lan YL, Chen WL, Wang YF, et al. Development and preliminary testing of a virtual reality measurement for assessing intake assessment skills[J].Int J Psychol, 2023,58(3):237-246. DOI:10.1002/ijop.12898.
[28] Haber Y, Hadar Shoval D, Levkovich I, et al.The externalization of internal experiences in psychotherapy through generative artificial intelligence: a theoretical, clinical, and ethical analysis[J].Front Digit Health, 2025,7:1512273. DOI:10.3389/fdgth.2025.1512273.
[29] Abbasian M, Khatibi E, Azimi I, et al. Foundation metrics for evaluating effectiveness of healthcare conversations powered by generative AI[J].NPJ Digit Med, 2024,7(1):82. DOI:10.1038/s41746-024-01074-z.
[30] Mannan M, Palipana DB, Mulholland K, et al. Virtual reality mediated brain-computer interface training improves sensorimotor neuromodulation in unimpaired and post spinal cord injury individuals[J].Sci Rep, 2026,16(1):6215. DOI:10.1038/s41598-026-36431-3.
[31] Sharma V, Park S, Voinescu A, et al.Medical students′ experiences with virtual reality simulation training: qualitative study[J].JMIR Med Educ, 2026,12:e74301. DOI:10.2196/74301.
[32] 黄欣, 蔡煜锋, 胡德华, 等. 基于PatSnap数据库的医疗领域脑机接口技术专利分析[J].世界科技研究与发展,2024,46(6):814-830. DOI:10.16507/j.issn.1006-6055.2024.06.002.
[33] 《脑机接口关键科学问题、关键核心技术及其布局研究》项目组, 肖松, 程和平, 等. 脑机接口技术发展现状及未来展望[J].科学与社会,2024,14(3):1-25. DOI:10.19524/j.cnki.10-1009/g3.2024.03.002.
[34] 郭佳莹, 杨洁莹, 李耀华. 医疗领域脑机接口技术和美国FDA监管现状浅析[J].中国医疗器械杂志,2025,49(1):96-102. DOI:10.12455/j.issn.1671-7104.240187.
[35] 张翔. 基于数字孪生技术的医疗网络数据安全保护系统设计[J].智能物联技术,2025,57(1):71-74. DOI:10.26921/j.cnki.2096-6059.2025.01.015.
[36] Dafli E, Antoniou P, Ioannidis L, et al. Virtual patients on the semantic Web: a proof-of-application study[J].J Med Internet Res, 2015,17(1):e16. DOI:10.2196/jmir.3933.
[37] 倪红波. 从大数据视角浅议对医院信息化和网络数据安全建设[J].数字通信世界,2023(7):172-174,178. DOI:10.3969/J.ISSN.1672-7274.2023.07.054.
[38] 吴腾. 生成式人工智能技术赋能智慧医疗建设的风险与规制[J].医学与社会,2025,38(3):9-16. DOI:10.13723/j.yxysh.2025.03.002.
[39] 孙琦, 吕晗, 王振常. 消除健康数据中的算法偏见:STANDING Together共识的启示[J].数字医学与健康,2025,3(1):10-11. DOI:10.3760/cma.j.cn101909-20241231-00240.