Biomedical Microdevices

, Volume 12, Issue 3, pp 381–387

An implantable Teflon chip holding lithium naphthalocyanine microcrystals for secure, safe, and repeated measurements of pO2 in tissues

Authors

  • Ramasamy P. Pandian
    • Center for Biomedical EPR Spectroscopy and ImagingThe Ohio State University
    • Department of Internal MedicineThe Ohio State University
    • Davis Heart and Lung Research InstituteThe Ohio State University
  • Guruguhan Meenakshisundaram
    • Center for Biomedical EPR Spectroscopy and ImagingThe Ohio State University
    • Department of Internal MedicineThe Ohio State University
    • Davis Heart and Lung Research InstituteThe Ohio State University
  • Anna Bratasz
    • Center for Biomedical EPR Spectroscopy and ImagingThe Ohio State University
    • Department of Internal MedicineThe Ohio State University
    • Davis Heart and Lung Research InstituteThe Ohio State University
  • Edward Eteshola
    • Department of Biomedical EngineeringThe Ohio State University
    • Davis Heart and Lung Research InstituteThe Ohio State University
  • Stephen C. Lee
    • Department of Biomedical EngineeringThe Ohio State University
    • Davis Heart and Lung Research InstituteThe Ohio State University
    • Center for Biomedical EPR Spectroscopy and ImagingThe Ohio State University
    • Department of Internal MedicineThe Ohio State University
    • Davis Heart and Lung Research InstituteThe Ohio State University
Article

DOI: 10.1007/s10544-009-9394-5

Cite this article as:
Pandian, R.P., Meenakshisundaram, G., Bratasz, A. et al. Biomed Microdevices (2010) 12: 381. doi:10.1007/s10544-009-9394-5

Abstract

Lithium naphthalocyanine (LiNc) is a crystalline material that has significant potential as a probe for EPR (electron paramagnetic resonance)-based biological oximetry (Pandian et al. J. Mater. Chem. 19:4138–4147, 2009a). However, implantation of LiNc crystals in tissues in raw or neat form is undesirable since dispersion of crystals in tissue may lead to loss of EPR signal, while also exacerbating biocompatibility concerns due to tissue exposure. To overcome these concerns, we have encapsulated LiNc crystals in an oxygen-permeable polymer, Teflon AF 2400 (TAF). Fabrication of TAF films incorporating LiNc particles (denoted as LiNc:TAF chip) was carried out using solvent-evaporation techniques. The EPR linewidth of LiNc:TAF chip was linearly dependent on oxygen-partial pressure (pO2) and did not change significantly relative to neat LiNc crystals. LiNc:TAF chip responded to changes in pO2 reproducibly, enabling dynamic measurements of oxygenation in real time. The LiNc:TAF chips were stable in tissues for more than 2 months and were capable of providing repeated measurements of tissue oxygenation for extended periods of time. The results demonstrated that the newly fabricated, highly oxygen-sensitive LiNc:TAF chip will enhance the applicability of EPR oximetry for long-term and clinical applications.

Keywords

EncapsulationOxygen permeabilityEPR oximetryImplantable biosensorTeflonLithium naphthalocyanine

Copyright information

© Springer Science+Business Media, LLC 2009