Preclinical Study of Radiation on Fat Flap Regeneration under Tissue-engineering Chamber: Potential Consequences for Breast Reconstruction.

Unlabelled: Use of a tissue-engineering chamber (TEC) for growth of fat flap is a promising approach for breast reconstruction. Here, we evaluated in a preclinical model the effects of radiation on adipose tissue growth either before or after 3D-printed bioresorbable TEC implantation.

Methods: Twenty-eight female Wistar rats were distributed into three groups: TEC implantation as nonirradiated controls (G1), TEC insertion followed by irradiation 3 weeks later (G2), and irradiation 6 weeks before TEC insertion (G3).

Effects of Two Melt Extrusion Based Additive Manufacturing Technologies and Common Sterilization Methods on the Properties of a Medical Grade PLGA Copolymer.

Although bioabsorbable polymers have garnered increasing attention because of their potential in tissue engineering applications, to our knowledge there are only a few bioabsorbable 3D printed medical devices on the market thus far. In this study, we assessed the processability of medical grade Poly(lactic--glycolic) Acid (PLGA)85:15 via two additive manufacturing technologies: Fused Filament Fabrication (FFF) and Direct Pellet Printing (DPP) to highlight the least destructive technology towards PLGA. To quantify PLGA degradation, its molecular weight (gel permeation chromatography (GPC)) as well as its thermal properties (differential scanning calorimetry (DSC)) were evaluated at each processing step, including sterilization with conventional methods (ethylene oxide, gamma, and beta irradiation).

Rationale for the design of 3D-printable bioresorbable tissue-engineering chambers to promote the growth of adipose tissue.

Tissue engineering chambers (TECs) bring great hope in regenerative medicine as they allow the growth of adipose tissue for soft tissue reconstruction. To date, a wide range of TEC prototypes are available with different conceptions and volumes. Here, we addressed the influence of TEC design on fat flap growth in vivo as well as the possibility of using bioresorbable polymers for optimum TEC conception.