Mark Van Dyke, Ph.D.
- Tissue engineering
Biomaterials are an essential tool that provide the basis for bioengineered devices, growing and delivering cells, developing functional tissues, and engineering whole organs. Natural biopolymers that self-assemble on the nano scale have the potential to provide native cellular environments that facilitate the directed behavior of cells.
Research conducted in the Nanostructured Biopolymer Engineering Lab makes use of naturally derived keratin nanomaterials for biomaterials development. Dr. Van Dyke’s research group studies the fundamental characteristics of keratin nanomaterials such as their solution behavior, self-assembly into network structures, and structure-function relationships. Keratin nanomaterials can be purified from natural fibers and when properly isolated, demonstrate several remarkable characteristics.
First, keratin nanomaterials are highly biocompatible and can be used for tissue regeneration, drug delivery, and as carriers for cells; purified keratin nanomaterials contain no cellular elements so they do not elicit an immune response.
Second, keratin nanomaterials have a unique capacity for molecular self-assembly that results in the spontaneous formation of network structures. Self-assembly occurs on the nanometer scale and builds to the micron scale, resulting in homogenous, porous architectures that are conducive to cell attachment and growth.
Third, keratin nanomaterials contain cellular binding motifs that mimic the sites of cell attachment found in native extracellular matrix. By leveraging these unique characteristics, we are creating inexpensive biomaterials with the potential for use in a host of biomedical applications. Commercializing the results of our research is also a focus of the lab.
Our current research programs are directed toward developing greater understanding of the molecular self-assembly process and keratin’s ligand-like function. We have projects that are aimed toward clinical applications such as heart regeneration, inflammation, and bone repair.
- University of Cincinnati: Ph.D., Materials Science, 1998
- Central Michigan University: B.S., Chemistry, 1988
Kathawala MH, Ng WL, Liu D, Naing MW, Yeong WY, Spiller K, Van Dyke M, Ng KW. Healing of chronic wounds - An update of recent developments and future possibilities. Tissue Engineering Part B: Rev 2019 (in press)
Thonnes S, Shelton P, Bracey D, Van Dyke M, Whitlock P, Smith TL, Moghaddam A, Tuohy C. Success and efficiency of cell seeding in avian tendon xenografts - a promising alternative for tendon and ligament reconstruction. Journal of Orthopaedics 2019 (in press)
Trent A, Van Dyke M. Development and characterization of a biomimetic coating for percutaneous devices. Colloids and Surfaces B: Biointerfaces 2019:182; 110351 (in press)
Bracey DN, Seyler TM, Jinnah AH, Lively MO, Willey JS, Smith TL, Van Dyke ME, Patrick W. Whitlock PW. A decellularized porcine xenograft-derived bone scaffold for clinical use as a bone graft substitute: A critical evaluation of processing and structure. Journal of Functional Biomaterials 2018;9(3):45. doi: 10.3390/jfb9030045
Potter NA, Van Dyke M. Effects of differing purification methods on properties of keratose biomaterials. ACS Biomaterial Science & Engineering 2018;4(4):1316-1323. DOI: 10.1021/acsbiomaterials.7b00964
Waters M, VandeVord P, Van Dyke M. Keratin biomaterials augment anti-inflammatory macrophage phenotype in vitro. Acta Biomater 2018;66:213-223
Parker R, Roth K, Van Dyke M, Grove T. Homo- and heteropolymer self-assembly of trichocytic keratins. Biopolymers 2017;107(10). doi:10.1002/bip.23037
Ledford BT, Simmons J, Chen M, Fan H, Barron C, Liu Z, Van Dyke M, He JQ. Keratose hydrogels promote vascular smooth muscle differentiation from C-kit-positive human cardiac stem cells. Stem Cells Dev 2017;26(12):888-900
Bayon Y, Van Dyke M, Buelher R, Tubo R, Bertram T, Malfroy-Camine B, Rathman M, Ronfard V. How regenerative medicine stakeholders adapt to ever-changing technology and regulatory challenges? Snapshots from the World TERMIS Industry Symposium (September 10, 2015, Boston). Tissue Eng Part B Rev 2017;23(2):159-62
Ronfard V, Vertès AA, May MH, Dupraz A, Van Dyke ME, Bayon Y. Evaluating the past, present, and future of regenerative medicine: A global view. Tissue Eng Part B Rev 2017;23(2):199-210