Abstract

A major obstacle to the widespread application of implantable glucose sensors is that they progressively lose function after a relatively short period of time in vivo. This loss of function is in part a consequence of inflammation and fibrosis resulting from the tissue trauma caused by the sensor implantation and by reactions within the tissue. For an implantable glucose sensor, mere tissue toleration of the device is not sufficient; the sensor must also remain functional. It must be emphasize that although it is known that tissue reactions plays an important role in loss of sensor's function, the specific contribution of each tissue reactions (i.e. inflammation, fibrosis and loss of vasculature) has not yet been determined nor quantified. Furthermore, little work has been done so far on controlling these reactions to implanted biosensors. Based on the preceding information, we have developed the following hypotheses. Grant Hypotheses: We hypothesize that inflammation, fibrosis and loss of vasculature affect both the transport properties and the local concentration of glucose around the implanted sensor. As a result, implanted glucose sensors progressively lose function and become unreliable after implantation. We further hypothesize that our experiments and mathematical models will show that all three-tissue reactions play a significant role in the loss of sensor function. However, we also hypothesize that use of an anti-inflammatory drug delivery system, with an anti-fibrotic decorated surface hydrogel, and VEGF gene transfer can enhance the function and lifespan of the implanted sensors by decreasing inflammation and fibrosis, as well as by enhancing neovascularization. To test these hypotheses, we propose to use the current electrochemical Nation-based glucose sensor developed in our laboratory and all in vivo experiments will be conducted in the rat model. Therefore, the goals of this proposal will be: 1) to determine the specific contributions of inflammation, fibrosis and blood vessel density on the sensor's loss of function, using in vitro and in vivo studies as well as mathematical models, and 2) to control these reactions using a combination of approaches (decorated hydrogels, drug delivery and gene transfer) to enhance the glucose sensor's function and lifetime in vivo. Our overall goal for this proposal is to have a glucose sensor that can be implanted and provide reliable and continuous monitoring for at least 4 weeks.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
5R01EB001640-04
Application #
7115710
Study Section
Special Emphasis Panel (ZRG1-SSS-A (50))
Program Officer
Lee, Albert
Project Start
2003-09-01
Project End
2007-08-31
Budget Start
2006-09-01
Budget End
2007-08-31
Support Year
4
Fiscal Year
2006
Total Cost
$408,261
Indirect Cost

  Institution

Name
University of South Florida
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
069687242
City
Tampa
State
FL
Country
United States
Zip Code
33612

  Publications

Burugapalli, Krishna; Wijesuriya, Shavini; Wang, Ning et al. (2018) Biomimetic electrospun coatings increase the in vivo sensitivity of implantable glucose biosensors. J Biomed Mater Res A 106:1072-1081
Wang, Ning; Burugapalli, Krishna; Wijesuriya, Shavini et al. (2014) Electrospun polyurethane-core and gelatin-shell coaxial fibre coatings for miniature implantable biosensors. Biofabrication 6:015002
Wang, Ning; Burugapalli, Krishna; Song, Wenhui et al. (2013) Tailored fibro-porous structure of electrospun polyurethane membranes, their size-dependent properties and trans-membrane glucose diffusion. J Memb Sci 427:207-217
Wang, Ning; Burugapalli, Krishna; Song, Wenhui et al. (2013) Electrospun fibro-porous polyurethane coatings for implantable glucose biosensors. Biomaterials 34:888-901
Ju, Young Min; Yu, Bazhang; West, Leigh et al. (2010) A dexamethasone-loaded PLGA microspheres/collagen scaffold composite for implantable glucose sensors. J Biomed Mater Res A 93:200-10
Zhu, Zhigang; Song, Wenhui; Burugapalli, Krishna et al. (2010) Nano-yarn carbon nanotube fiber based enzymatic glucose biosensor. Nanotechnology 21:165501
Ju, Young Min; Yu, Bazhang; West, Leigh et al. (2010) A novel porous collagen scaffold around an implantable biosensor for improving biocompatibility. II. Long-term in vitro/in vivo sensitivity characteristics of sensors with NDGA- or GA-crosslinked collagen scaffolds. J Biomed Mater Res A 92:650-8
Rey, Jose I; Huang, Haihong; Sheng, Ling et al. (2009) In vivo imaging using tissue specific near infrared fluorescent peptide conjugate, c[RGDyK(HiLyte Fluor 750]. Adv Exp Med Biol 611:447-8
Yu, Bazhang; Wang, Chunyan; Ju, Young Min et al. (2008) Use of hydrogel coating to improve the performance of implanted glucose sensors. Biosens Bioelectron 23:1278-84
Wang, Chunyan; Yu, Bazhang; Knudsen, Bernard et al. (2008) Synthesis and performance of novel hydrogels coatings for implantable glucose sensors. Biomacromolecules 9:561-7

Showing the most recent 10 out of 18 publications