文學軍,男,1971年5月24日生,河南林州人。美國醫(yī)學與生物工程院院士 [1],美國諾維斯NOVIS抗衰科技創(chuàng)始人。美國弗吉尼亞聯(lián)邦大學William H. Goodwin首席冠名終身席正教授 [2],同濟大學特聘講座教授 [3]。魯東大學特聘教授 [4]。博士研究生導師 [2]。主要從事三維打印生物制造、生物材料、納米技術、干細胞技術、組織工程和再生醫(yī)學的研究和技術應用,包括3D打印人工器官,全合成生物材料、天然改性抗菌生物材料、可注射型水凝膠等在神經系統(tǒng)、軟骨、心臟,肌肉,血管,角膜、皮膚等組織修復中的應用等 [2] [5]。
- 中文名
- 文學軍
- 籍 貫
- 河南林州
- 出生日期
- 1971年5月24日
- 畢業(yè)院校
- 美國猶他大學
- 教學職稱
- 教授
- 性 別
- 男
2003年7月至2012年8月歷任美國克萊姆森大學生物醫(yī)學工程系助理教授、副教授、終身教授,并于2010年09月獲美國南卡州命名的Hansj?rg Wyss首席冠名終身席正教授職 [6]。
文學軍率先研發(fā)了天然改性抗細菌生物膜材料——塑化蛋白抑菌納米涂層技術并產業(yè)化 [8],開發(fā)了高活性超短繞圈狀(looped)全合成多肽 [9]用于干細胞培養(yǎng),來替代細胞外基質的大分子蛋白質和生長因子 [9]。和張寧教授 [10-11]一起發(fā)明了用于腦損傷和中風修復的可注射型水凝膠,可在無外源性干細胞移植的條件下,利用內源性干細胞實現(xiàn)受損區(qū)域的網絡化血管重建和神經再生,使失去知覺的鼠模型恢復到正常水平 [12]。該成果于2009年9月份受到BBC [13], Discovery [14]等媒體的關注報道。發(fā)明了用于急性脊髓損傷的再生材料 [15],在大鼠動物模型上實現(xiàn)了受損脊椎神經的再生和修復,修復后的動物運動能力恢復BBB評分超過10 [15]。利用計算機輔助和三維打印技術制造出與原生椎間盤最近似的椎間盤替代產品——高仿生椎間盤 [16],2011年3月被美國麻省理工學院(MIT)TechnologyReview進行了專題介紹 [17]。首次采用非細胞移植的方法,利用自體內源性干細胞在兔動物模型上實現(xiàn)了功能性透明軟骨的再生,再生的軟骨高度表達透明軟骨特異的II型膠原蛋白 [18]。
持有89項世界領先的核心技術,在2007-2014年間主持和參與30多個科研項目,總經費超過3000萬美元。
2008年榮獲美國國家科學基金青年科學家成就獎 [19-20]。2012年當選世界生物工程領域聲譽最高的學術組織美國醫(yī)學與生物工程院(American Institute for Medical and BiologicalEngineering)院士(Fellow) [1]。獲得Sigma XI杰出青年科學家年度獎(2008) [21],克萊門森大學校董事會獎(2008、2009、2010、2011、2012) [22],克萊門森大學McQueen-Quattlebaum成就獎(2010),Michael J. Fox基金會應用人干細胞治療帕金森病獎(2005) [23-24],Coulter基金會生物工程技術臨床轉化獎(2006),蘇州工業(yè)園區(qū)科技領軍人才(2011) [25]和蘇州市姑蘇領軍人才計劃(2013) [26]。
截止2014年10月,在《Progress in Polymer Science》 [27-28]、《FASEB Journal》 [29]、《Advanced Functional Materials》 [30]、《Advanced healthcare Materials》 [31]、《Journal of Neuroscience》 [32]、《Biomaterials》 [33-35]等學術期刊上發(fā)表論文100多篇。
2015年11月18日,作為特邀主講嘉賓中的大學教授,出席于美國加利福尼亞州硅谷舉辦的2015美國3D打印會議暨展覽會,并發(fā)表題為“先進生物制造技術”的主題演講 [37]。
2009年,在文學軍院士主導下,美國弗吉尼亞聯(lián)邦大學再生醫(yī)學實驗室、生物制造實驗室共建并成立“NOVIS生物科技聯(lián)合實驗室” [38],開展NAD+抗衰老研發(fā)與轉化課題項目。文學軍團隊利用再生醫(yī)學和生物工程將諾貝爾NAD+逆轉衰老科研成果成功實現(xiàn)產品化,并將其命名為諾維斯(NOVIS)。央視《影響力時代》欄目特邀文學軍教授做客欄目,與知名主持人水均益一起暢享生命科學未來。該成果受到美通社、華爾街、美國先驅日報、美國晨報等國際媒體關注。2019年8月31日,未來健康前沿學術高峰論壇——暨諾維斯“未來生命標準”新聞發(fā)布會在國家會議中心隆重召開。 [39]
1. Fabrication of three dimensional aligned nanofiber array; USPTO Issue # 7,828,539 [40]
2. Polysaccharide-Based Biomaterials; USPTO Issue # 7,914,819 [41]
3. Fabrication Of Nanofiber Reinforced Structures For Tissue Engineering; WO/2010/096795
4. Synthetic vascular tissue and method of forming the same; USPTO Issued # 8,124,001 [42]
5. Fabrication of three dimensional aligned nanofiber array; USPTO Issue # US 8580181 B1
6. Novel Material and Method for the Programmed Treatment of Diabetic Ulcers or Periodontal Diseases; ID: 12/856299
7. Injectable hydrogels prepared via synergic covalent and ionic crosslinking.
8. Treatment of brain injury and stroke using injectable hydrogels [43]
9. Delivery Devices And Methods For Long-Term Delivery Into Ear And Eye
10. Devices And Methods For Improved Viability Of Transplanted Cells
等80多項技術。
1. Beachley, V. and X. Wen, Polymer nanofibrous structures: Fabrication, biofunctionalization, and cell interactions. Progress in Polymer Science, 2010. 35(7): p. 868-892. [27]
2. Li, X., E. Katsanevakis, X. Liu, N. Zhang, and X. Wen, Engineering neural stem cell fates with hydrogel design for central nervous system regeneration. Progress in Polymer Science, 2012. 37(8): p. 1105-1129. [28]
3. Beachley, V., E. Katsanevakis, N. Zhang, and X. Wen, A Novel Method to Precisely Assemble Loose Nanofiber Structures for Regenerative Medicine Applications. Advanced Healthcare Materials, 2013. 2(2): p. 343-351. [31]
4. Deng, L.-X., P. Deng, Y. Ruan, Z.C. Xu, N.-K. Liu, X. Wen, G.M. Smith, and X.-M. Xu, A Novel Growth-Promoting Pathway Formed by GDNF-Overexpressing Schwann Cells Promotes Propriospinal Axonal Regeneration, Synapse Formation, and Partial Recovery of Function after Spinal Cord Injury. Journal of Neuroscience, 2013. 33(13): p. 5655-5667. [32]
5. Li, X., X. Liu, L. Cui, C. Brunson, W. Zhao, N.R. Bhat, N. Zhang, and X. Wen, Engineering an in situ crosslinkable hydrogel for enhanced remyelination. Faseb Journal, 2013. 27(3): p. 1127-1136. [29]
6. Li, X., X. Liu, B. Josey, C.J. Chou, Y. Tan, N. Zhang, and X. Wen, Short Laminin Peptide for Improved Neural Stem Cell Growth. Stem Cells Translational Medicine, 2014. 3(5): p. 662-670. [44]
7. Wen, X.J. and P.A. Tresco, Fabrication and characterization of permeable degradable poly(DL-lactide-co-glycolide) (PLGA) hollow fiber phase inversion membranes for use as nerve tract guidance channels. Biomaterials, 2006. 27(20): p. 3800-3809. [33]
8. Wen, X.J. and P.A. Tresco, Effect of filament diameter and extracellular matrix molecule precoating on neurite outgrowth and Schwann cell behavior on multifilament entubulation bridging device in vitro. Journal of Biomedical Materials Research Part A, 2006. 76A(3): p. 626-637.
9. Whatley, B.R., J. Kuo, C. Shuai, B.J. Damon, and X. Wen, Fabrication of a biomimetic elastic intervertebral disk scaffold using additive manufacturing. Biofabrication, 2011. 3(1). [16]
10. Whatley, B.R., X. Li, N. Zhang, and X. Wen, Magnetic-directed patterning of cell spheroids. Journal of Biomedical Materials Research Part A, 2014. 102(5): p. 1537-1547. [45]
11. Zdyrko, B., V. Klep, X. Li, Q. Kang, S. Minko, X. Wen, and I. Luzinov, Polymer brushes as active nanolayers for tunable bacteria adhesion. Materials Science & Engineering C, 2009. 29(3): p. 680-684. [46]
12. Zhang, C., X. Wen, N.R. Vyavahare, and T. Boland, Synthesis and characterization of biodegradable elastomeric polyurethane scaffolds fabricated by the inkjet technique. Biomaterials, 2008. 29(28): p. 3781-3791. [35]
13. Zhang, N., H.H. Yan, and X.J. Wen, Tissue-engineering approaches for axonal guidance. Brain Research Reviews, 2005. 49(1): p. 48-64. [47]
14. Zhao, J., N. Zhang, G.D. Prestwich, and X. Wen, Recruitment of endogenous stem cells for tissue repair. Macromolecular Bioscience, 2008. 8(9): p. 836-842. [48]
15. Zhao, W., X. Li, X. Liu, N. Zhang, and X. Wen, Effects of substrate stiffness on adipogenic and osteogenic differentiation of human mesenchymal stem cells. Materials Science & Engineering C, 2014. 40: p. 316-323. [49]
等100多篇論文。
美國 NIH, NSF, NASA, DOD, Veterans Affairs, Empire State Stem Cell Program (NYSTEM), American Chemical Society (ACS) Research Fund, American Heart Association (AHA), U.S. Civilian Research & Development Foundation (CRDF), Alzheimer’s Disease Association, North Carolina Biotechnology Center (Science & Technology Development Program), Alzheimer‘s & Related Diseases Research Award Fund (ARDRAF)等
加拿大 Canada Leader Opportunity Funds, Network of Centres of Excellence ofCanada
歐盟 Human Frontier Science Program
荷蘭 Technology Foundation STW (Netherlands),
瑞典 AO Foundation
俄羅斯 Skolkovo Institute of Science and Technology (SkTech) andMIT(SkTech/MIT Initiative),
拉脫維亞 education and science ministry
瑞士 Swiss National Science Foundation
意大利 Italian Ministry of Health
西班牙 Spain National Science Foundation
法國 Leducq Foundation
馬來西亞 Ministry of Science, Technology and Innovation Grant,
香港 Research Grants Council
Nature, Bone, Journal of Biomedical Materials Research, ASAIO Journal,Artificial Organ, Journal of Orthopedic Research, Langmuir, Journals of Materials Science, Advanced Materials, Biomaterials, Macromolecules, Biomacromolecules, Journal of Nanomaterials, Journal of Nanoscience and Nanotechnology, Nanomedicine, Journals of Materials Science: Materials in Medicine, Acta Biomaterialia, Journal of Neuroscience Methods, Journal of Biomaterial Applications, The Open Biomedical Engineering Journal, International Journal of Optomechatronics, Composites Science and Technology, Macromolecular Bioscience, Materials Science and Engineering, Tissue Engineering, Biofabrication, Journal of the Royal Society Interface, Proteomics, Applied Biochemistry and Biotechnology, PLoS One等
