Real-world Use of AlloDerm Acellular Dermal Matrix in Head and Neck Procedures in the United States.

Background: Real-world literature evaluating the use of AlloDerm SELECT Regenerative Tissue Matrix in head- and neck-related procedures is limited. To inform patient care decisions, this study evaluated healthcare resource utilization (HCRU) in US adults undergoing head- and neck-related procedures using AlloDerm.

Methods: A retrospective claims analysis was conducted using MarketScan Commercial and Medicare Supplemental Databases (study period: October 1, 2015, to March 31, 2022; index period: November 1, 2015, to March 1, 2022).

Microchannel-based regenerative scaffold for chronic peripheral nerve interfacing in amputees.

Neurally controlled prosthetics that cosmetically and functionally mimic amputated limbs remain a clinical need because state of the art neural prosthetics only provide a fraction of a natural limb's functionality. Here, we report on the fabrication and capability of polydimethylsiloxane (PDMS) and epoxy-based SU-8 photoresist microchannel scaffolds to serve as viable constructs for peripheral nerve interfacing through in vitro and in vivo studies in a sciatic nerve amputee model where the nerve lacks distal reinnervation targets. These studies showed microchannels with 100 μm × 100 μm cross-sectional areas support and direct the regeneration/migration of axons, Schwann cells, and fibroblasts through the microchannels with space available for future maturation of the axons.

Guiding intracortical brain tumour cells to an extracortical cytotoxic hydrogel using aligned polymeric nanofibres.

Glioblastoma multiforme is an aggressive, invasive brain tumour with a poor survival rate. Available treatments are ineffective and some tumours remain inoperable because of their size or location. The tumours are known to invade and migrate along white matter tracts and blood vessels.

Molecular sequelae of topographically guided peripheral nerve repair.

Peripheral nerve injuries cause severe disability with decreased nerve function often followed by neuropathic pain that impacts the quality of life. Even though use of autografts is the current gold standard, nerve conduits fabricated from electrospun nanofibers have shown promise to successfully bridge critical length nerve gaps. However, in depth analysis of the role of topographical cues in the context of spatio-temporal progression of the regenerative sequence has not been elucidated.

Regenerative scaffold electrodes for peripheral nerve interfacing.

Advances in neural interfacing technology are required to enable natural, thought-driven control of a prosthetic limb. Here, we describe a regenerative electrode design in which a polymer-based thin-film electrode array is integrated within a thin-film sheet of aligned nanofibers, such that axons regenerating from a transected peripheral nerve are topographically guided across the electrode recording sites. Cultures of dorsal root ganglia were used to explore design parameters leading to cellular migration and neurite extension across the nanofiber/electrode array boundary.

Effect of modulating macrophage phenotype on peripheral nerve repair.

Peripheral nerve repair across long gaps remains clinically challenging despite progress made with autograft transplantation. While scaffolds that present trophic factors and extracellular matrix molecules have been designed, matching the performance of autograft-induced repair has been challenging. In this study, we explored the effect of cytokine mediated 'biasing' of macrophage phenotypes on Schwann cell (SC) migration and axonal regeneration in vitro and in vivo.

Photocrosslinkable chitosan based hydrogels for neural tissue engineering.

Hydrogel based scaffolds for neural tissue engineering can provide appropriate physico-chemical and mechanical properties to support neurite extension and facilitate transplantation of cells by acting as 'cell delivery vehicles'. Specifically, gelling systems such as photocrosslinkable hydrogels can potentially conformally fill irregular neural tissue defects and serve as stem cell delivery systems. Here, we report the development of a novel chitosan based photocrosslinkable hydrogel system with tunable mechanical properties and degradation rates.

The use of lipid microtubes as a novel slow-release delivery system for laryngeal injection.

Objectives/hypothesis: The potential utility of direct injection of bioactive substances in the treatment of vocal fold tissue fibrosis is limited by rapid clearance from the injection site. The objective of this study is to evaluate the potential of a lipid-based microtube delivery system to preserve the biological activity of injected substances and prolong their duration of pharmacological effects in the larynx.

Study Design: Prospective in vitro and case-control in vivo murine study

Methods: Lipid-based microtubes were loaded with Texas red-dextran (MT-TR) and hepatocyte growth factor (MT-HGF).

Role of fibronectin in topographical guidance of neurite extension on electrospun fibers.

Bridging of long peripheral nerve gaps remains a significant clinical challenge. Electrospun nanofibers have been used to direct and enhance neurite extension in vitro and in vivo. While it is well established that oriented fibers influence neurite outgrowth and Schwann cell migration, the mechanisms by which they influence these cells are still unclear.

Advances in bioengineered conduits for peripheral nerve regeneration.

Although resorbable NGCs have been developed for peripheral nerve grafting, there has been little published on their use as a material for trigeminal nerve repair. Advances in engineered guidance channels and modifications to the single-lumen conduit with growth-permissive substrates, ECM proteins, neurotrophic factors, and supportive Schwann or stem cells, and anisotropic placement of these within the NGC may translate from animal models to clinical human use in the future. A great deal of research is still needed to optimize the presently available NGCs, and their use in peripheral trigeminal nerve repair and regeneration remains yet to be explored.

Influence of nanoporous alumina membranes on long-term osteoblast response.

A major goal of bone tissue engineering is to design better scaffold configuration and materials to better control osteoblast behavior. Nanoporous architecture has been shown to significantly affect cellular response. In this work, nanoporous alumina membranes were fabricated by a two-step anodization method to investigate bone cell response.