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TMJ Disc Regeneration

$368,021R01FY2015DENIH

University Of California At Davis, Davis CA

Investigators

Linked publications & trials

Abstract

DESCRIPTION (provided by applicant): The objective of this renewal is to respond to two commonly observed clinical problems in temporomandibular joint (TMJ) disease by engineering a biomimetic TMJ disc complex. This will subsequently be implanted in a porcine animal model. The overall hypothesis is that the implantation of an anatomically-shaped, robust TMJ disc, engineered with attachments and containing appropriate matrix anisotropy, will be able to address TMJ disc perforation (via a patch approach) and TMJ disc lateral defects (via a subtotal approach). The following three specific aims are proposed to test this hypothesis: 1) to characterize the bulk and interfacial properties of the discal attachments, 2) to engineer an anatomically-correct TMJ disc with attachments, and 3) implant this engineered TMJ disc complex in a porcine animal model with clinically representative in vivo defects. While in the previous grant the properties of the TMJ disc were investigated to inform the engineering of the TMJ disc, collaboration with TMJ surgeons has highlighted the functional importance of the disc attachments. Aim 1 will inform the engineering of the TMJ disc and attachments for Aim 2, by characterizing the biochemical composition, biomechanical properties, and cellular population of the disc attachments and interface. The previous grant also identified the need for a biological TMJ disc replacement to match the native tissue shape and organization. It also recognized the costal cartilage as an alternative cell source for TMJ disc engineering. Therefore, Aim 2 will use this cell source to generate robust constructs with anisotropic features for implantation in Aim 3, and the properties of this TMJ disc complex will be modified using ion channel modulators, a matrix remodeling enzyme, and a tension-compression bioreactor. Finally, Aim 3 will devise methods to surgically access the TMJ, and for the first time, implant and secure an engineered TMJ disc complex in vivo, to fill clinically relevant TMJ disc defects in a porcine model. This proposal seeks to: 1) characterize the discal attachments and their function in the TMJ, to 2) inform the tissue engineering of a functional biological replacement TMJ disc complex, and 3) develop a surgical approach to implant this replacement. PHS 398/2590 (Rev. 06/09) Page Continuation Format Page

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