脑机接口与人机交互联合实验室简介

脑机接口与人机交互联合实验室是由广东省智能科学与技术研究院与NeuroXess脑虎科技共同建设。致力于打破国外技术垄断,建立起自身在柔性电极、生物材料、芯片设计、核心算法、植入方式、临床应用、生态建设等多环节的全面领先优势。我们希望通过自身努力,在2025年前成为该领域的全球领导者。

联合实验室主任简介

联合实验室联合主任张旭院士,2021年6月任广东省智能科学与技术研究院院长,兼任中国神经科学学会理事长、中国细胞生物学学会副理事长、中华医学会疼痛分会副主任委员、上海脑-智工程中心主任等职。

联合实验室联合主任陶虎,NeuroXess(脑虎)创始人兼首席科学家,中国科学院上海微系统与信息技术研究所副所长、2020前沿实验室创始主任、传感技术国家重点实验室副主任中国神经科学学会脑机接口与交互分会主任委员、上海市未来产业脑机接口专委会主任委员、“中国脑机接口产业技术路线图研究”项目负责人。

主要从事生命科技与信息技术交叉前沿研究,创新地将蚕丝转化为新型医用和信息功能材料,围绕脑机接口、智能感知和生物存储等方面展开深入研究。主持多项国家和省部级科研项目,包括科技创新2030“新一代人工智能”重大专项、中国科学院基础前沿“从0到1”项目等。凭借精湛的学术造诣和对前沿科技的突出贡献,陶虎荣获2020上海市青年科技杰出贡献奖、2021中国科学院青年科学家奖、2021世界人工智能大会最高奖SAIL奖(卓越人工智能引领者奖)、2022转化医学创新奖、2023上海青年科技英才、2023上海市大众科学传播杰出人物,连续入选爱思唯尔发布的“中国高被引学者”和美国斯坦福大学发布的“全球前2%顶尖科学家”榜单,并五次荣获“中国科学院优秀导师”和三次荣获“中国科学院大学振翅奖”。


科研项目:

1. 基于生物蛋白的绿色纳米光刻技术研究, 主持, 国家级, 2016-01--2019-12

2. 基于蚕丝蛋白的生态环保型高分子生物光刻胶的研究与开发, 主持, 省级, 2014-07--2017-06

3. 多模态超衍射近场太赫兹光谱仪, 主持, 部委级, 2018-01--2019-12

4. 精准可控溶解的瞬态电子技术研究, 主持, 部委级, 2017-01--2019-12

5. 上海市“优秀学术带头人”, 主持, 省级, 2018-01--2019-12

6. 面向新一代人工智能的新型感知器件和芯片技术, 主持, 国家级, 2019-12--2024-12

7. 瞬态可溶电子学, 主持, 国家级, 2019-01--2021-12

8. “神经光电极”:光电集成柔性神经探针, 主持, 部委级, 2019-09--2024-08

 

代表性论文:

1. In Situ Regulation of Macrophage Polarization to Enhance Osseointegration Under Diabetic Conditions Using Injectable Silk/Sitagliptin Gel Scaffolds, ADVANCED SCIENCE, 2021,

2. Silk Materials Light Up the Green Society, Advanced Energy & Sustainability Research, 2021,

3. Biomimicking Antibacterial Opto-Electro Sensing Sutures Made of Regenerated Silk Proteins, ADVANCED MATERIALS, 2021,

4. 3D electron-beam writing at sub-15 nm resolution using spider silk as a resist, NATURE COMMUNICATIONS, 2021,

5. Silk Microneedle Patch Capable of On-Demand Multidrug Delivery to the Brain for Glioblastoma Treatment, ADVANCED MATERIALS, 2021,

6. 实现“人机物”三元融合——谈脑机接口中的人脑优势发挥, 前沿科学, 2021, 第 1 作者

7. Biomimicking antibacterial and pharmaceutical opto-electro sensing suture made of regenerated silk proteins, Advanced Materials, 2020, 通讯作者

8. Nanomanufacturing of biopolymers using electron and ion beams, JOURNAL OF MICROMECHANICS AND MICROENGINEERING, 2020,

9. Implantable, Degradable, Therapeutic Terahertz Metamaterial Devices (封面论文), SMALL, 2020,

10. A Bioinspired Wireless Epidermal Photoreceptor for Artificial Skin Vision, ADVANCED FUNCTIONAL MATERIALS, 2020,

11. A rewritable optical storage medium of silk proteins using near-field nano-optics, NATURE NANOTECHNOLOGY, 2020,

12. Body-Integrated, Enzyme-Triggered Degradable, Silk-Based Mechanical Sensors for Customized Health/Fitness Monitoring and In Situ Treatment, ADVANCED SCIENCE, 2020,

13. Photoinduced Tunable and Reconfigurable Electronic and Photonic Devices Using a Silk‐Based Diffractive Optics Platform, ADVANCED SCIENCE, 2020,

14. All-Aqueous-Processed Injectable In Situ Forming Macroporous Silk Gel Scaffolds for Minimally Invasive Intracranial and Osteological Therapies, ADVANCED HEALTHCARE MATERIALS, 2020,

15. "Self-Matched" Tribo/Piezoelectric Nanogenerators Using Vapor-Induced Phase-Separated Poly(vinylidene fluoride) and Recombinant Spider Silk, ADVANCED MATERIALS, 2020,

16. Programmable Vanishing Multifunctional Optics, ADVANCED SCIENCE, 2019,

17. Advanced modeling of ferroic materials, ARCHIVE OF APPLIED MECHANICS, 2019,

18. Multicolor T-Ray Imaging Using Multispectral Metamaterials (封面论文), ADVANCED SCIENCE, 2018,

19. Engineering the Future of Silk Materials through Advanced Manufacturing, ADVANCED MATERIALS, 2018,

20. Protein Bricks: 2D and 3D Bio-Nanostructures with Shape and Function on Demand, ADVANCED MATERIALS, 2018,

21. METAMATERIALS TO SEE IN TERAHERTZ IN "COLORS", 2018 IEEE MICRO ELECTRO MECHANICAL SYSTEMS (MEMS), 2018,

22. A Silk Cranial Fixation System for Neurosurgery, ADVANCED HEALTHCARE MATERIALS, 2018,

23. The Use of Functionalized Silk Fibroin Films as a Platform for Optical Diffraction-Based Sensing Applications, ADVANCED MATERIALS, 2017,

24. 2D AND 3D FUNCTIONAL NANOSTRUCTURES OF GENETICALLY ENGINEERED SPIDER SILK USING FOCUSED ION BEAM, 30TH IEEE INTERNATIONAL CONFERENCE ON MICRO ELECTRO MECHANICAL SYSTEMS (MEMS 2017), 2017,

25. Nanoscale probing of electron-regulated structural transitions in silk proteins by near-field IR imaging and nano-spectroscopy, NATURE COMMUNICATIONS, 2016,

26. Inkjet Printing of Functional Silk Fibroin Inks: From Printable Forms to Printable Functions, Advanced Materials, 2015, 第 1 作者

27. Silk-based resorbable electronic devices for remotely controlled therapy and in vico infection abatement, PNAS, 2014, 第 1 作者

28. Silk‐Enabled Conformal Multifunctional Bioelectronics for Investigation of Spatiotemporal Epileptiform Activities and Multimodal Neural Encoding/Decoding, publisher,


脑虎科技简介

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NeuroXess 脑虎科技是一家通过柔性脑机接口技术来保护及探索大脑的生命科技公司。通过脑机接⼝技术重塑和强化⼈的感知与认知,进⽽保护、探索并延伸⼤脑边界,让HI(⼈类智能)与AI(⼈⼯智能)实现从交互、到共⽣、再到孪⽣的发展。

 

脑虎科技官网及微信公众号:

官网:http://www.neuroxess.com/

微信公众号:NeuroXess脑虎科技


脑机接口与人机交互联合实验室