Xingyu Jiang is a Chair Professor and Departmental Head at the Department of Biomedical Engineering of the Southern University of Science and Technology (2018-present). Born (1977) and raised in Chengdu, China, Xingyu attended Nanjing University (Nanjing, China in 1995) and went to the US finish undergraduate studies, obtaining his Bachelor of Science at the University of Chicago (1999), followed by an AM (2001) and a PhD (2004) from Harvard University (Chemistry), working with Professor George Whitesides on surface chemistry and cell patterning. After a short postdoctoral fellowship with Professor George Whitesides, he joined the National Center for NanoScience and Technology of China (NCNST), which is part of the Chinese Academy of Sciences (CAS), in 2005. In 2018, he moved to the Department of Biomedical Engineering of the Southern University of Science and Technology, as a Chair Professor and Departmental Head. He is a “Hundred Talents Plan” professor, and was a National Distinguished Young Scholar Awardee by the National Science Foundation of China (2010). He is a fellow of the Royal Society of Chemistry and the American Institute of Medical and Biological Engineering. He is an awardee of the Tencent Explore Prize. He was the past president of the Chinese American Society of Nanomedicine and Nanobiotechnology. Xingyu has published over 340 papers in peer-reviewed journals has an H-index of 80. These papers have a collective citation of > 25,000.

Xingyu’s research interests include analytical chemistry, microfluidics, biomedical engineering, and nano/bio medicine.

Papers

representative papers

1. Thermo-triggered release of CRISPR-Cas9 system by lipid-encapsulated gold nanoparticles for tumor therapy, Wang P, Zhang LM, Zheng WF, Cong LM, Guo ZR, Xie YZY, Wang L, Tang RB, Feng Q, Hamada Y, Gonda K, Hu ZJ, Wu XC, Jiang XY, Angew Chem Int Ed, 57, 1491-1496. (2018).

2. Skiving stacked sheets of paper into test paper for rapid and multiplexed assay, Yang MZ, Zhang W, Yang JC, Hu BF, Cao FJ, Zheng WS, Chen YP, Jiang XY, Science Advances, 3, eaao4862. (2017).

3. Self-adjusting, polymeric multilayered roll that can keep the shapes of the blood vessel scaffolds during biodegradation, Cheng SY, Jin Y, Wang NX, Cao F, Zhang W, Bai W, Zheng WF, Jiang XY, Adv Mater, 29(28), 1700171. (2017).

4. Gold nanoclusters-assisted delivery of NGF siRNA for effective treatment of pancreatic cancer, Lei YF, Tang LX, Xie YZY, Xianyu YL, Zhang LM, Wang P, Hamada Y, Jiang K, Zheng WF, Jiang XY, Nature Communications, 8, 15130. (2017).

5. Surface modification of gold nanoparticles with small molecules for biochemical analysis, Chen YP, Xianyu YL, Jiang XY, Accounts Chem Res, 50(2), 310-319. (2017).

6. Microfluidic synthesis of rigid nanovesicles for hydrophilic reagents delivery, Zhang L, Feng Q, Wang JL, Sun JS, Shi XH, Jiang XY. Angew Chem Int Ed, 54(13), 3952-3956. (2015).

7. Tunable rigidity of (polymeric core)-(lipid shell) nanoparticles for regulated cellular uptake, Sun JS, Zhang L, Wang JD, Feng Q, Liu DB, Yin QF, Xu DY, Wei YJ, Ding BQ, Shi XH, Jiang XY, Adv Mater, 27(8), 1402-1407. (2015).

8. Tuning the composition of AuPt bimetallic nanoparticles for antibacterial application, Zhao Y, Ye C, Liu W, Chen R, Jiang XY, Angew Chem Int Ed, 53(31), 8127-8131. (2014). (Inside Cover)

9. Identification of bacteria in water by a fluorescent array, Chen WW, Li QZ, Zheng WS, Hu F, Zhang GX, Wang Z, Zhang DQ, Jiang XY, Angew Chem Int Ed, 53(50), 13734-13739. (2014).

10. Point-of-care biochemical assays using gold nanoparticle-implemented microfluidics, Sun JS, Xianyu YL, Jiang XY, Chem Soc Rev, 43(17), 6239-6253. (2014).

11. Synergy of non-antibiotic drugs and pyrimidinethiol on gold nanoparticles against superbugs, Zhao YY, Chen ZL, Chen YF, Xu J, Li JH, Jiang XY, J Am Chem Soc, 135(35), 12940-12943. (2013).

12. Nanomaterials for ultrasensitive protein detection, Zhang Y, Guo YM, Xianyu YL, Chen WW, Zhao YY, Jiang XY, Adv Mater, 25(28), 3802-3819. (2013).

13. A Strategy for the construction of controlled, three-dimensional, multilayered, tissue-like structures, Gong PY, Zheng WF, Huang Z, Zhang W, Xiao D, Jiang XY, Adv Funct Mater, 23(1), 42-46. (2013).

14. Resettable, multi-readout logic gates based on controllably reversible aggregation of gold nanoparticles, Liu DB, Chen WW, Sun K, Deng K, Zhang W, Wang Z, Jiang XY, Angew Chem Int Ed, 50(18), 4103-4107. (2011).

15. Copper-mediated amplification allows readout of immunoassays by the naked eye, Qu WS, Liu YY, Liu DB, Wang Z, Jiang XY, Angew Chem Int Ed, 50(15), 3442-3445. (2011).

16. Small molecule-capped gold nanoparticles as potent antibacterial agents that target gram-negative bacteria, Zhao YY, Tian Y, Cui Y, Liu WW, Ma WS, Jiang XY, J Am Chem Soc, 132(35), 12349-12356. (2010).

17. Patterning mammalian cells for modeling three types of naturally occurring cell-cell interactions, Chen ZL, Li Y, Liu WW, Zhang DZ, Zhao YY, Yuan B, Jiang XY, Angew Chem Int Ed, 48(44), 8303-8305. (2009).

18. Using azobenzene-embedded self-assembled monolayers to photochemically control cell adhesion reversibly, Liu DB, Xie YY, Shao HW, Jiang XY, Angew Chem Int Ed, 48(24), 4406-4408. (2009).

19. Visual detection of copper(II) by azide- and alkyne-functionalized gold nanoparticles using click chemistry, Zhou Y, Wang SX, Zhang K, Jiang XY, Angew Chem Int Ed, 47(39), 7454-7456. (2008).

20. Electrospun nanofibrous membranes: a novel solid substrate for microfluidic immunoassays for HIV, Yang DY, Niu X, Liu YY, Wang Y, Gu X, Song LS, Zhao R, Ma LY, Shao YM, Jiang XY, Adv Mater, 20(24), 4770-4775. (2008).

21. Fabrication of aligned fibirous arrays by magnetic electrospinning, Yang DY, Lu B, Zhao Y, Jiang XY, Adv Mater, 19(21),3702-3706. (2007).

22. A method for patterning multiple types of cells by using electrochemical desorption of self-assembled monolayers within microfluidic channels, Li Y, Yuan B, Ji H, Han D, Chen SQ, Tian F, Jiang XY, Angew Chem Int Ed, 46(7), 1094-1096. (2007).

Research

 Analytical Chemistry, Microfluidics, Biomedical Engineering, and Nano/bio Medicine

Teaching

Main Course：Introduction to nano biomedicine