破局“卡脖子”: 构建国产科学仪器“研发-应用-推广”新生态

doi:10.5246/jcps.2026.01.007

中国药学(英文版) ›› 2026, Vol. 35 ›› Issue (1): 88-97.DOI: 10.5246/jcps.2026.01.007

• 【研究论文】 • 上一篇

破局“卡脖子”: 构建国产科学仪器“研发-应用-推广”新生态

许迎利, 王静, 师晓萌, 袁霞, 王倩, 宋书香^*()

北京大学药学院天然药物及仿生药物全国重点实验室, 北京 100191

收稿日期:2025-10-11 修回日期:2025-11-06 接受日期:2025-11-17 出版日期:2026-01-31 发布日期:2026-01-31
通讯作者: 宋书香

Breaking the stranglehold on key technologies: building an integrated “R&D-Application-Promotion” ecosystem for domestic scientific instruments

Yingli Xu, Jing Wang, Xiaomeng Shi, Xia Yuan, Qian Wang, Shuxiang Song^*()

State Key Laboratory of Natural and Biomimetic Drugs, School of Pharmaceutical Sciences, Peking University, Beijing 100191, China

Received:2025-10-11 Revised:2025-11-06 Accepted:2025-11-17 Online:2026-01-31 Published:2026-01-31
Contact: Shuxiang Song
Supported by:
Management Research Project on the Transformation of Scientific and Technological Achievements at Peking University Health Science Center (Grant No. KT202501) and Peking University Health Science Center 2025 Party Building Research Project (General Category, No. 2).

摘要/Abstract

摘要：

科学仪器是驱动科研探索与产业创新的核心引擎, 其自主可控关乎国家科技安全与长远发展。当前, 我国高端科学仪器领域面临严峻的“卡脖子”风险, 根源在于核心技术积累不足以及应用推广环节存在深层次的生态与机制障碍。例如, 90%的高端科学仪器依赖进口, 这凸显了中国在科技领域中的“卡脖子”困境。此外, 制造技术限制、资金和设备的不足、科研体制和创新机制的不完善, 都是导致这一现象的重要因素。本文旨在系统分析国产科学仪器推广难的原因, 并结合实践, 提出通过组织用户走进企业、召开国产仪器替代研讨会、建设应用与推广示范中心、参与国产仪器研发升级等路径, 构建以信任为基础、以需求为牵引、以协同为内核的“研发-应用-推广”新生态, 为打通国产科学仪器从“能用”到“好用”再到“愿用”的“最后一公里”, 为实现高水平科技自立自强提供理论支撑与实践参考。

关键词: 国产科学仪器, 卡脖子, 应用推广, 产学研用, 科技自立自强

Abstract:

Scientific instruments serve as foundational pillars for both scientific progress and industrial innovation, enabling deep exploration and driving technological breakthroughs. Their independent controllability and continuous innovation are indispensable for sustaining a competitive advantage in technological development, thereby securing national scientific capacity and long-term strategic growth. At present, however, China faces substantial risks of technological “stranglehold” in the high-end scientific instrument domain. The underlying causes are multifaceted, arising not only from insufficient accumulation of core technologies but also from entrenched systemic and ecosystem-level barriers that impede the application, scaling, and promotion of domestic instruments. This paper provides a systematic analysis of the challenges hindering the widespread adoption of domestically developed scientific instruments and proposes practical pathways to build a new, integrated “R&D-application-promotion” ecosystem. This ecosystem is anchored in trust, driven by user demand, and shaped through collaborative innovation. Key initiatives include organizing user visits to instrument manufacturers, convening seminars on domestic alternatives to imported equipment, establishing demonstration centers for application and promotion, and involving end-users directly in the R&D and iterative upgrading of domestic instruments. Together, these efforts aim to close the final critical gap, advancing domestic instruments from merely “functional” to genuinely “user-friendly”, and ultimately to “widely implemented”. By doing so, this framework offers both theoretical grounding and practical guidance for achieving high-level scientific and technological self-reliance and sustained innovation capacity.

Key words: Domestic scientific instruments, Stranglehold of key technology, Application promotion, Industry-university-research-application collaboration, Scientific and technological self-reliance and strengthening

Supporting:

许迎利, 王静, 师晓萌, 袁霞, 王倩, 宋书香. 破局“卡脖子”: 构建国产科学仪器“研发-应用-推广”新生态[J]. 中国药学(英文版), 2026, 35(1): 88-97.

Yingli Xu, Jing Wang, Xiaomeng Shi, Xia Yuan, Qian Wang, Shuxiang Song. Breaking the stranglehold on key technologies: building an integrated “R&D-Application-Promotion” ecosystem for domestic scientific instruments[J]. Journal of Chinese Pharmaceutical Sciences, 2026, 35(1): 88-97.

图/表 4

Figure 1. Difficulties in the application and promotion of domestic scientific instruments.

Figure 2. Practical pathways to build a new ecosystem for the application and promotion of domestic scientific instruments.

Figure 3. Sensorgrams of imported SPR instrument (A) and domestic SPR instrument (B).

Table 1. Comparison of experimental data between imported instrument (A) and domestic instrument (B).

参考文献 10

[1]	Xu, Z.G.; He, Y.T.; Jin, F.M.; Wu, A.H.; Liu, Y.L.; Xu, M.; Liu, J.F.; Zhang, L.N. Promoting the development of domestic scientific research instruments: relevant measures and practices. Exp. Technol. Manag. 2025, 42, 1–7.
[2]	National Natural Science Foundation of China. Application and funding of National Major Scientific Research Instrument Development Project. 2024 Annual Report of the National Natural Science Foundation of China. This report can be found online at https://www.nsfc.gov.cn/p1/2991/3821/3824/3830/90794.html.
[3]	Pan, X.F.; Wang, W.G. Development and application of domestic analytical instruments. Chem. Eng. Des. Commun. 2019, 45, 87–88.
[4]	Yang, J.; Zhang. L.N.; Wu, A.H. Exploring the demonstration and promotion model of domestic scientific instrument application: a case study of the China instrument and meter society evaluation center. Society. 2022, 7, 44–47.
[5]	Song, S.X. Discussion of the process control of large-scale instruments and equipment procurement in State Key Laboratory. J. Chin. Pharm. Sci. 2020, 29, 214–219.
[6]	Lai, H.S.; Su, R.X. Comparison of the results of five thyroid function tests using different chemiluminescent immunoassay devices. China Med. Device Inf. 2024, 30, 57–59.
[7]	Yang, T.; Li, Bo. Performance validation of Ningbo Meikang MS-880B Automatic Biochemical Analyzer. Int. J. Lab. Med. 2017, 38, 1007–1008.
[8]	Wang, J.; Wang, Q.; Song, S.X. Research progress of surface plasmon resonance technology in drug discovery. J. Chin. Pharm. Sci. 2020, 29, 504–513.
[9]	Li, L.; Yang, Y. Discussion on the upgrading and transformation of university instrumentation. Anal. Instrum. 2025, 5, 59–62.
[10]	Yao, W.L.; Xiong, D.C.; Yang, Y.; Geng, C.M.; Cong, Z.S.; Li, F.F.; Li, B.H.; Qin, X.J.; Wang, L.N.; Xue, W.Y.; Yu, N.F.; Zhang, H.Y.; Wu, X.; Liu, M.; Ye, X.S. Automated solution-phase multiplicative synthesis of complex glycans up to a 1, 080-mer. Nat. Synth. 2022, 1, 854–863.

破局“卡脖子”: 构建国产科学仪器“研发-应用-推广”新生态

Breaking the stranglehold on key technologies: building an integrated “R&D-Application-Promotion” ecosystem for domestic scientific instruments

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