Abstract

The field of Biomaterials significantly impacts the quality of life of thousands of people. Biomaterials have traditionally been used in medical devices such as hip implants, vascular grafts, and stents with new evolving applications in scaffolds/drug delivery devices for tissue engineering and regenerative medicine. However, significant challenges remain with the ability of Biomaterials to integrate seamlessly with the body, to respond and remodel with time in vivo. The full potential of Biomaterials has not yet been realized, in part, because most materials that are used today are by-products of other processes, not rationally designed with the specific medical requirements in mind. Biomedical engineering as a discipline offers a unique opportunity to address this shortcoming. Georgia Institute of Technology has had an excellent, interdisciplinary graduate program in Bioengineering for 15 years with a high quality of pre-doctoral students. The goal of GTBioMAT (Graduate Training for Rationally Designed, Integrative Biomaterials) is to leverage the existing inter-departmental and inter-university ties and provide a structured, focused, integrative training for the rational design and application of the next generation of biomimetic, integrative materials. The GTBioMAT training program will focus on integrating four important skill sets that are critical to training the future leaders in Biomaterials science and engineering: 1) the ability to elucidate Biomaterials design criteria through strong clinical interactions;2) the ability to synthesize and characterize new materials whose design is driven by an understanding of the underlying clinical and basic science issues;3) the ability to functionalize and apply these materials such that they integrate appropriately into living systems;and 4) develop leadership skills in the trainees such that they lead the next generation of Biomaterials Science and Engineering research through their innovation and research. The GTBioMAT training program proposes to introduce novel problem based learning approaches that promote self-directed inquiry and collaborative problem solving of complex but authentic biomaterials related problems. It leverages the strong research strength of the faculty at Georgia Institute of Technology and Emory University and will significantly impact the training of the future leaders in Biomaterials.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Institutional National Research Service Award (T32)
Project #
5T32EB006343-05
Application #
8287009
Study Section
Special Emphasis Panel (ZEB1-OSR-E (M1))
Program Officer
Baird, Richard A
Project Start
2008-07-01
Project End
2014-06-30
Budget Start
2012-07-01
Budget End
2014-06-30
Support Year
5
Fiscal Year
2012
Total Cost
$173,343
Indirect Cost
$8,714

  Institution

Name
Georgia Institute of Technology
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
097394084
City
Atlanta
State
GA
Country
United States
Zip Code
30332

  Publications

Schudel, Alex; Sestito, Lauren F; Thomas, Susan N (2018) Winner of the society for biomaterials young investigator award for the annual meeting of the society for biomaterials, April 11-14, 2018, Atlanta, GA: S-nitrosated poly(propylene sulfide) nanoparticles for enhanced nitric oxide delivery to lymphatic tiss J Biomed Mater Res A 106:1463-1475
Sago, Cory D; Lokugamage, Melissa P; Paunovska, Kalina et al. (2018) High-throughput in vivo screen of functional mRNA delivery identifies nanoparticles for endothelial cell gene editing. Proc Natl Acad Sci U S A 115:E9944-E9952
Holt, Brandon Alexander; Mac, Quoc D; Kwong, Gabriel A (2018) Nanosensors to Detect Protease Activity In Vivo for Noninvasive Diagnostics. J Vis Exp :
Paunovska, Kalina; Gil, Carmen J; Lokugamage, Melissa P et al. (2018) Analyzing 2000 in Vivo Drug Delivery Data Points Reveals Cholesterol Structure Impacts Nanoparticle Delivery. ACS Nano 12:8341-8349
Miller, Ian C; Gamboa Castro, Marielena; Maenza, Joe et al. (2018) Remote Control of Mammalian Cells with Heat-Triggered Gene Switches and Photothermal Pulse Trains. ACS Synth Biol 7:1167-1173
Krishnan, Laxminarayanan; Priddy, Lauren B; Esancy, Camden et al. (2017) Delivery vehicle effects on bone regeneration and heterotopic ossification induced by high dose BMP-2. Acta Biomater 49:101-112
McNerney, Monica P; Styczynski, Mark P (2017) Precise control of lycopene production to enable a fast-responding, minimal-equipment biosensor. Metab Eng 43:46-53
Holt, Brandon Alexander; Bellavia, Michael C; Potter, Daniel et al. (2017) Fc microparticles can modulate the physical extent and magnitude of complement activity. Biomater Sci 5:463-474
Zurla, C; Jung, J; Blanchard, E L et al. (2017) A Novel Method to Quantify RNA-Protein Interactions In Situ Using FMTRIP and Proximity Ligation. Methods Mol Biol 1468:155-70
Alonas, Eric; Vanover, Daryll; Blanchard, Emmeline et al. (2016) Imaging viral RNA using multiply labeled tetravalent RNA imaging probes in live cells. Methods 98:91-98

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