Thomas J. Webster

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Thomas J. Webster
NationalityAmerican
EducationUniversity of Pittsburgh
Rensselaer Polytechnic Institute
Scientific career
FieldsBiomedical engineering
Chemical engineering
Nanomedicine
InstitutionsNortheastern University, Purdue University, Brown University, Hebei Institute of Technology, Saveetha University, Federal University of Piaui
ThesisDesign, synthesis, and evaluation of nanophase ceramics for orthopaedic/dental applications (2000)
Doctoral advisorsRena Bizios
Richard W. Siegel

Thomas J. Webster is an American biomedical engineer, researcher, and entrepreneur. Throughout his over 25-year academic career, his research group has produced several books and book chapters. He has over 1350 publications and has an H-index of 118. This high H-index places him amongst the top 1% of researchers in his field.[1]

Education[edit]

Thomas J. Webster holds a BSc degree in chemical engineering from the University of Pittsburgh (Pittsburgh, PA, USA; 1995), and an MSc and PhD (2000) in biomedical engineering from Rensselaer Polytechnic Institute (Troy, NY, USA). Rensselaer Polytechnic Institute is the oldest engineering school in the U.S.[2][3]

Research[edit]

The research of Professor Webster examines the multiple uses of nanotechnology. His study focuses on the development, production, and assessment of nanophase materials as superior biomedical materials.[4] Professor Webster has conducted in-depth research on the application of nanophase materials for tissue regeneration.[5][6] His research has focussed on hydroxyapatite, the major inorganic component to bone.[7][8][9] In contrast to hydroxyapatite that had not been doped, Professor Webster's research on osteoblast (bone-forming cells) response to hydroxyapatite doped with divalent and trivalent cations showed that osteoblast adherence and differentiation on the doped HA were boosted.[10][11] In other research, he creates surfaces with nanostructures that have been FDA-approved for implantation in tissues like bone, the spine, and dental applications.[12]

In addition, he is particularly involved in creating nanoparticles that may enter biofilms, lessen inflammation, and specifically target cancer cells.[13][14] Dr. Webster was the first to identify improved tissue growth on nanomaterials.[6][15] He was the first to identify decreased bacteria functions on nanomaterials.[16][17][18] Dr. Webster was the first to establish a mathematical equation that can be used to predict nanoscale surface features to improve tissue growth, reduce infection, and limit infection.[19] He trademarked this process as “Nano-Optimized”, 2008.[20]

Career[edit]

With more than 25 years of professional experience, Webster is presently the chief nano scientific officer at PrinterPrezz in Fremont, California, and serves as the chief scientific officer of his numerous start-up companies. He started his career as an assistant professor at the Purdue University. His research on nanomedicine has received attention in media including MSNBC, NBC Nightly News, PBS DragonFly TV, ABC Nightly News via the Ivanhoe Medical Breakthrough Segment, Fox News, the Weather Channel, NBC Today Show, National Geographic's TV series on the future of medicine, ABC Boston, Discovery Channel, and OpenAccess Government.[21][22][23][24] His work has been on display at the London and Boston Science Museums.[25][26]

Awards and honors[edit]

Thomas J. Webster has been honored with many awards including the

  • BMES Rita Schaffer Young Investigator Award (2002),[27]

Prof. Webster has received numerous honors including, but not limited to:[21][30]

  • 2002, Biomedical Engineering Society Rita Schaffer Young Investigator Award;
  • 2003, Outstanding Young Investigator Award Purdue University College of Engineering;
  • 2005, American Association of Nanomedicine Young Investigator Award;
  • 2005, Coulter Foundation Young Investigator Award;
  • 2006, Fellow, American Association of Nanomedicine;
  • 2010, Distinguished Lecturer in Nanomedicine, University of South Florida;
  • 2011, Outstanding Leadership Award for the Biomedical Engineering Society (BMES);
  • 2012, Fellow, American Institute for Medical and Biological Engineering (AIMBE, representing the top 2% of all medical and biological engineers);
  • 2013, Fellow, Biomedical Engineering Society;
  • 2014, Fellow, Ernst Strugmann;
  • 2016, Fellow, College of Fellows of the International Union of Biomaterials Sciences and Engineering;
  • 2016, SCOPUS Highly Cited Research (Top 1% Materials Science);[31]
  • 2017, Fellow, National Associate of Inventors;
  • 2017, Acta Biomaterialia Silver Award (given to researchers under the age of 45);
  • 2019, Overseas Fellow, Royal Society for Medicine;
  • 2000, SCOPUS Top 1% citations for materials science research and mixed fields;
  • 2021, PLOS Top 2% All World Scientist Citations;[31]
  • 2022, Clarivate Most Distinguished Researcher Top 0.1% Citations in Pharmacology and Toxicology;
  • 2022, Fellow, International Association for Advanced Materials; and
  • 2023, Research.com Best Materials Science Scientist by Citations.

Editorships[edit]

Thomas J. Webster is serving as the Editor-in-chief of the Research Journal of Medical and Health Sciences and was the founding editor-in-chief of the International Journal of Nanomedicine pioneering the open-access format.[32]

Patents[edit]

Thomas J. Webster has obtained many patents for his inventions and his patents including

  • Nanotubes as carriers of nucleic acids into cells (US10344300B2)[33]
  • System and method for attaching soft tissue to an implant (US8945601B2)[34]
  • Nanofibers as a neural biomaterial (US7993412B2)[35]
  • Nanotubes and compositions thereof (US10201634B2)[36]
  • Implantable cellular and biotherapeutic agent delivery canister (US10751280B2)[37]
  • Method for producing nanostructures on a surface of a medical implant (US20110125263A1)[38]
  • Nanostructured surfaces (US11560014B2),[39]
  • Tellurium Nanostructures with antimicrobial and anticancer properties synthesized by aloe vera–Mediated green chemistry (US20220071919A1)[40]
  • Metallic nanoparticles as orthopedic biomaterial (EP1613248B1)[41]
  • Antipathogenic surfaces having selenium nanoclusters (WO2012009433A1)[42]

These patents have formed many companies who have commercial products including but not limited to Audax, NanoVis, NanoVis Spine, Perios, Dental Regen, Quarksen, SynCell, Novaraum, AKiCept, Zeda, MetaFree, Interstellar Therapeutics, etc.

Publications[edit]

Prof. Webster and his team have published over 1350 peer-reviewed publications: This high H-index places him in the top 1% of cited articles by researchers in Materials Science.

An example of these articles appear below:

  • Thomas J Webster, Celaletdin Ergun, Robert H Doremus, Richard W Siegel, Rena Bizios; Enhanced functions of osteoblasts on nanophase ceramics. Biomaterials.[43]
  • Thomas J Webster, Celaletdin Ergun, Robert H Doremus, Richard W Siegel, Rena Bizios. Specific proteins mediate enhanced osteoblast adhesion on nanophase ceramics. Journal of Biomedical Materials Research.[44]
  • Thomas J Webster, Jeremiah U Ejiofor. Increased osteoblast adhesion on nanophase metals: Ti, Ti6Al4V, and CoCrMo. Biomaterials.[45]
  • Thomas J Webster, Celaletdin Ergun, Robert H Doremus, Richard W Siegel, Rena Bizios. Enhanced osteoclast-like cell functions on nanophase ceramics. Biomaterials.[46]
  • Thomas J Webster, Linda S Schadler, Richard W Siegel, Rena Bizios. Mechanisms of enhanced osteoblast adhesion on nanophase alumina involve vitronectin. Tissue engineering.[47]

References[edit]

  1. ^ "thomas j webster". scholar.google.co.in. Retrieved 2023-07-10.
  2. ^ "Thomas J Webster | Materials Science Conferences | Materials Conferences | Material Science and Engineering Congress 2024". magnusconferences.com. Retrieved 2023-07-10.
  3. ^ Press, Dove. "Dr Thomas J Webster | Dove Press editor profile". www.dovepress.com. Retrieved 2023-07-10.
  4. ^ Nicodemo, Allie (2017-12-13). "Thomas Webster named Fellow of National Academy of Inventors". Northeastern Global News. Retrieved 2023-07-10.
  5. ^ Webster, Thomas J (September 2007). Nanotechnology for the Regeneration of Hard and Soft Tissues. doi:10.1142/6421. ISBN 978-981-270-615-7.
  6. ^ a b Zhang, Lijie; Webster, Thomas J. (2009-02-01). "Nanotechnology and nanomaterials: Promises for improved tissue regeneration". Nano Today. 4 (1): 66–80. doi:10.1016/j.nantod.2008.10.014. ISSN 1748-0132.
  7. ^ Balasundaram, Ganesan; Sato, Michiko; Webster, Thomas J. (2006-05-01). "Using hydroxyapatite nanoparticles and decreased crystallinity to promote osteoblast adhesion similar to functionalizing with RGD". Biomaterials. 27 (14): 2798–2805. doi:10.1016/j.biomaterials.2005.12.008. ISSN 0142-9612. PMID 16430957.
  8. ^ Kargozar, Saeid; Mollazadeh, Sahar; Kermani, Farzad; Webster, Thomas J.; Nazarnezhad, Simin; Hamzehlou, Sepideh; Baino, Francesco (September 2022). "Hydroxyapatite Nanoparticles for Improved Cancer Theranostics". Journal of Functional Biomaterials. 13 (3): 100. doi:10.3390/jfb13030100. ISSN 2079-4983. PMC 9326646. PMID 35893468.
  9. ^ Webster, Thomas J.; Ahn, Edward S. (2007), Lee, Kyongbum; Kaplan, David (eds.), "Nanostructured Biomaterials for Tissue Engineering Bone", Tissue Engineering II: Basics of Tissue Engineering and Tissue Applications, Advances in Biochemical Engineering/Biotechnology, vol. 103, Berlin, Heidelberg: Springer, pp. 275–308, doi:10.1007/10_021, ISBN 978-3-540-36186-2, PMID 17195467, retrieved 2023-07-10
  10. ^ Yao, Chang; Slamovich, Elliott B.; Webster, Thomas J. (April 2008). "Enhanced osteoblast functions on anodized titanium with nanotube-like structures". Journal of Biomedical Materials Research Part A. 85A (1): 157–166. doi:10.1002/jbm.a.31551. PMID 17688267.
  11. ^ MacMillan, Adam K.; Lamberti, Francis V.; Moulton, Julia N.; Geilich, Benjamin M.; Webster, Thomas J. (2014-12-02). "Similar healthy osteoclast and osteoblast activity on nanocrystalline hydroxyapatite and nanoparticles of tri-calcium phosphate compared to natural bone". International Journal of Nanomedicine. 9 (1): 5627–5637. doi:10.2147/IJN.S66852. PMC 4260657. PMID 25506216.
  12. ^ Jones, A-Andrew D.; Mi, Gujie; Webster, Thomas J. (February 2019). "A Status Report on FDA Approval of Medical Devices Containing Nanostructured Materials". Trends in Biotechnology. 37 (2): 117–120. doi:10.1016/j.tibtech.2018.06.003. ISSN 0167-7799. PMID 30075863. S2CID 51909976.
  13. ^ Bhardwaj, Garima; Yazici, Hilal; Webster, Thomas J. (2015-04-30). "Reducing bacteria and macrophage density on nanophase hydroxyapatite coated onto titanium surfaces without releasing pharmaceutical agents". Nanoscale. 7 (18): 8416–8427. Bibcode:2015Nanos...7.8416B. doi:10.1039/C5NR00471C. ISSN 2040-3372. PMID 25876524.
  14. ^ Shi, Di; Mi, Gujie; Wang, Mian; Webster, Thomas J. (2019-04-01). "In vitro and ex vivo systems at the forefront of infection modeling and drug discovery". Biomaterials. Organoids and Ex Vivo Tissue On-Chip Technologies. 198: 228–249. doi:10.1016/j.biomaterials.2018.10.030. ISSN 0142-9612. PMC 7172914. PMID 30384974.
  15. ^ Alpaslan, Ece; Webster, Thomas J. (2014-05-05). "Nanotechnology and picotechnology to increase tissue growth: a summary of in vivo studies". International Journal of Nanomedicine. 9 (Supplement 1): 7–12. doi:10.2147/IJN.S58384. PMC 4024972. PMID 24872699.
  16. ^ Yao, Chang; Webster, Thomas J.; Hedrick, Matthew (June 2014). "Decreased bacteria density on nanostructured polyurethane: Decreased Bacteria Density on Nanostructured Polyurethane". Journal of Biomedical Materials Research Part A. 102 (6): 1823–1828. doi:10.1002/jbm.a.34856. PMID 23784968.
  17. ^ Mathew, Dennis; Bhardwaj, Garima; Wang, Qi; Sun, Linlin; Ercan, Batur; Geetha, Manisavagam; Webster, Thomas J. (2014-04-08). "Decreased Staphylococcus aureus and increased osteoblast density on nanostructured electrophoretic-deposited hydroxyapatite on titanium without the use of pharmaceuticals". International Journal of Nanomedicine. 9 (1): 1775–1781. doi:10.2147/IJN.S55733. PMC 3986289. PMID 24748789.
  18. ^ Machado, Mary C.; Tarquinio, Keiko M.; Webster, Thomas J. (2012-07-19). "Decreased Staphylococcus aureus biofilm formation on nanomodified endotracheal tubes: a dynamic airway model". International Journal of Nanomedicine. 7: 3741–3750. doi:10.2147/IJN.S28191. PMC 3418105. PMID 22904622.
  19. ^ Benjamin, T. B.; Bona, J. L.; Mahony, J. J. (1972-03-30). "Model equations for long waves in nonlinear dispersive systems". Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences. 272 (1220): 47–78. Bibcode:1972RSPTA.272...47B. doi:10.1098/rsta.1972.0032. ISSN 0080-4614. S2CID 120673596.
  20. ^ "openaccessgovernment.org".
  21. ^ a b "Nanomedicine - 2nd Edition". shop.elsevier.com. Retrieved 2023-07-10.
  22. ^ "openaccessgovernment.org".
  23. ^ Outreach, Research (2022-07-21). "Nanomedicine for the prevention and treatment of COVID-19 and other viruses". Research Outreach. Retrieved 2023-07-10.
  24. ^ "openaccessgovernment.org".
  25. ^ Reis, Rui L. "Thomas J Webster". International College of Fellows Biomaterials Science & Engineering. Retrieved 2023-07-10.
  26. ^ "northeastern.edu" (PDF).
  27. ^ "BMES Rita Schaffer Young Investigator Award - Biomedical Engineering Society". www.bmes.org. Retrieved 2023-07-10.
  28. ^ "Acta Biomaterialia Silver Medal Award - News - Materialia - Journal - Elsevier". www.journals.elsevier.com. Retrieved 2023-07-10.
  29. ^ "Thomas J. Webster, Ph.D." MAScIR. Retrieved 2023-07-10.
  30. ^ "lavoisier.eu".
  31. ^ a b "Thomas J Webster | Nanotechnology Conferences 2024 | Nanomaterials Conference 2024 | Nanomaterials Conferences | Nanoscience Conferences 2024 | Nano Event 2024". worldnanotechnologyconference.com. Retrieved 2023-07-10.
  32. ^ "Editorial Team | Research Journal in Medical and Health Sciences". royalliteglobal.com. Retrieved 2023-07-14.
  33. ^ US10344300B2, Chen, Yunpeng; Chen, Qian & Webster, Thomas J. et al., "Nanotubes as carriers of nucleic acids into cells", issued 2019-07-09 
  34. ^ US20030050711A1, Laurencin, Cato & Ko, Frank, "Hybrid nanofibril matrices for use as tissue engineering devices", issued 2003-03-13 
  35. ^ US7993412B2, Webster, Thomas J. & McKENZIE, Janice L., "Nanofibers as a neural biomaterial", issued 2011-08-09 
  36. ^ US10201634B2, Webster, Thomas J.; Fenniri, Hicham & Hemraz, Usha Devi, "Nanotubes and compositions thereof", issued 2019-02-12 
  37. ^ US10751280B2, Hennemann, Willard W.; Steelman, Bryan L. & Webster, Thomas J., "Implantable cellular and biotherapeutic agent delivery canister", issued 2020-08-25 
  38. ^ US20110125263A1, Webster, Thomas J. & Yao, Chang, "Method for producing nanostructures on a surface of a medical implant", issued 2011-05-26 
  39. ^ US11560014B2, Webster, Thomas J., "Nanostructured surfaces", issued 2023-01-24 
  40. ^ US20220071919A1, Cruz, David Medina; CRUA, Ada Vernet & Webster, Thomas J., "Tellurium Nanostructures with Antimicrobial and Anticancer Properties Synthesized by Aloe Vera-Mediated Green Chemistry", issued 2022-03-10 
  41. ^ EP1613248B1, Webster, Thomas J. & Ejiofor, Jeremiah U., "Metallic nanoparticles as orthopedic biomaterial", issued 2012-08-01 
  42. ^ WO2012009433A1, Webster, Thomas J. & Tran, Phong Anh, "Antipathogenic surfaces having selenium nanoclusters", issued 2012-01-19 
  43. ^ Webster, Thomas J; Ergun, Celaletdin; Doremus, Robert H; Siegel, Richard W; Bizios, Rena (2000-09-01). "Enhanced functions of osteoblasts on nanophase ceramics". Biomaterials. 21 (17): 1803–1810. doi:10.1016/S0142-9612(00)00075-2. ISSN 0142-9612. PMID 10905463.
  44. ^ Webster, Thomas J.; Ergun, Celaletdin; Doremus, Robert H.; Siegel, Richard W.; Bizios, Rena (2000-09-05). "Specific proteins mediate enhanced osteoblast adhesion on nanophase ceramics". Journal of Biomedical Materials Research. 51 (3): 475–483. doi:10.1002/1097-4636(20000905)51:3<475::AID-JBM23>3.0.CO;2-9. ISSN 0021-9304. PMID 10880091.
  45. ^ Webster, Thomas J.; Ejiofor, Jeremiah U. (2004-08-01). "Increased osteoblast adhesion on nanophase metals: Ti, Ti6Al4V, and CoCrMo". Biomaterials. 25 (19): 4731–4739. doi:10.1016/j.biomaterials.2003.12.002. ISSN 0142-9612. PMID 15120519.
  46. ^ Webster, Thomas J; Ergun, Celaletdin; Doremus, Robert H; Siegel, Richard W; Bizios, Rena (2001-06-01). "Enhanced osteoclast-like cell functions on nanophase ceramics". Biomaterials. 22 (11): 1327–1333. doi:10.1016/S0142-9612(00)00285-4. ISSN 0142-9612. PMID 11336305.
  47. ^ Webster, Thomas J.; Schadler, Linda S.; Siegel, Richard W.; Bizios, Rena (June 2001). "Mechanisms of Enhanced Osteoblast Adhesion on Nanophase Alumina Involve Vitronectin". Tissue Engineering. 7 (3): 291–301. doi:10.1089/10763270152044152. ISSN 1076-3279. PMID 11429149.

External links[edit]

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