Tissue engineering materials

Lloyd-Evans, M. Regulating Tissue Engineering. Materials Today 7 no. 5 (2004) 48-55. 

In biomedical applications, transglutaminases have been used for tissue engineering materials such as enzymatically crosslinked collagen [60-63] or gelatin scaffolds [64-69]. Even melt-extruded guides based on enzymatically crosslinked macromolecules for peripheral nerve repair have been reported [70]. 

Santeire JP et al (2005) Understanding the biodegradation of polyurethanes From classical implants to tissue engineering materials. Biomaterials 26(35) 7457-7470 Demir MM et al (2002) Electrospinning of polyurethane fibers. Polymer 43(11) 3303-3309... 

Zhou T, Braunhut SJ, Medeiros D, Marx KA (1999) In Mater Res Soc Symp biomedical materials drug delivery, implants and tissue engineering. Materials Research Society Pittsburgh PA 550 177... 

Chen, G. Q. Wu, Q. Biomater. 2005, 26(33), 6565-6578. The application of polyhy-droxyaUcanoates as tissue engineering materials. 

Cuy, J. L., Beckstead, B. L., Brown, C. D., Hoffman, A. S., Giachelli, C. M. Adhesive protein interactions with chitosan Consequences for valve endothelial cell growth on tissue-engineering materials. Journal of Biomedical Materials Research A. 2003, 67, 538-547. 

A biomaterial is any natural or synthetic material that is employed as. or part of. a medical device. Typical materials include metals, ceramics, glasses, polymers, and tissue-engineered materials. The requirements of a biomaterial are that it should have the correct properties to allow it to achieve its intended function and be biocompatible. Over recent decades, there have been many developments in biomaterials research. Some of these developments have involved a movement from the use of inert materials to more sophisticated ones, which actively invoke a beneficial response from the body. 

Chen G-Q, Wu Q (2005) The apphcation of polyhydroxyalkanoates as tissue engineering materials. Biomaterials 26 6565-6578... 

Understanding the biodegradation of pol30irethanes From classical Implants to tissue engineering materials, 26,7457-7470. 

R. T. Tran, P. Thevenot, Y. Zhang, D. Gyawali, L.P. Tang, J. Yang, Scaffold sheet design strategy fa- soft tissue engineering. Materials 3(2010)1375-1389. 

S. Wang, L. Lu, M.J. Yaszemski, Bone-tissue-engineering material poly(propylene fiimarate) corelation between molecular weight, chain dimensions, and physical properties. Biomacromolecules 7 (6) (2006) 1976-1982, doi 10.1021/bm060096a. 

P. Karimi, A.S. Rizkalla, K. Mequanint, Versatile biodegradable poly (ester amide)s derived from a-amino acids for vascular tissue engineering. Materials 3 (4) (2010) 2346-2368. 

J.P. Santerre, K. Woodhouse, G. Laroche, R.S. Labow, Understanding the biodegradation of polyurethanes from classical implants to tissue engineering materials. Biomabaials 26, 7457-7470 (2005)... 

O Brien, F.J. Biomaterials scaffolds for tissue engineering. Materials Today 14, 88-95 (2011)... 

PHA as tissue engineering materials PHA monomers and oligomers as nutritional and energy supplements PHA monomers as drugs PHA monomers as fine chemicals... 

CeccomUi G, PizzoU M, Scandola M (1993) Effect of a low-molecular-weight plasticizer on the thermal and viscoelastic properties of miscible blends of bacterial poly(3-hydroxybutyrate) with cellulose acetate butyrate. Macromolecules 26 6722-6726 Chanprateep S, Kikuya K, Shimizu H, Shioya S (2(X)2) Model predictive controller for biodegradable polyhydroxyalkanoate production in fed-batch culture. J Bacterid 95 157-169 Chen GQ, Wu Q (2005) The application of polyhydroxyalkanoates as tissue engineering materials. Biomaterials 26 6565-6578... 

Cameron NS, Corbierre MK, Eisenberg A (1999) Asymmetric amphiphilic block copolymers in solution a morphological wonderland. Can J Chem 77 1311-1326 Cheng GQ, Wu Q (2005) The application of polyhydroxyalkanoates as tissue engineering materials. Biomaterials 26 6565-6578... 

As mentioned before, HRN is DNA-based, hehcal nanofibers in the form of hydrogel that possesses attractive features for orthopedic tissue engineering. These features include (I) HRN has rich amino acid side chains with well-controlled spatial nanoscale distributions that impart more functionahty and versatility to meet a wide range of orthopedic needs (2) HRN hydrogel is able to solidify when heated or added directly into a serum-free medium, which allows them to serve as injectable tissue engineering materials and (3) HRN has demonstrated potential to enhance osteoblast adhesion and serve as an excellent calcification template [13,14], Based on these unique properties, HRN has been stndied or incorporated with other materials or molecules to create a better implantable material for enhancing bone regeneration. 

Ito, Y, Hasuda, H., Kamitakahara, M. et al. 2005. A composite of hydroxyapatite with elec-trospun biodegradable nanofibers as a tissue engineering material. 

Isobe, Y., et al. 2012. Oriented collagen scaffolds for tissue engineering. Materials 5(3) 501-511. 

Ghasemi-Mobarakeh, L., et al., 2010. Bio-functionalized PCL nanofibrous scaffolds for nerve tissue engineering. Materials Science and Engineering C 30 (8), 1129—1136. 

Wang, X.F., Ding, B., Li, B.Y., 2013. Biomimetic electrospun nanofibrous structures for tissue engineering. Materials Today 16, 229—241. 

Gerhardt, L., Boccaccini, A.R., 2010. Bioactive glass and gjass-ceramic scaffolds for bone tissue engineering. Materials 3 (7), 3867. 

Aydin, H.M., Kourush, S., Yilmaz, M., Turk, M., Rzayev, Z., Piskin, E., 2012. The catalyst assisted two stage synthesis of poly(glycerolco-sebacate-co-e-capiolactone) elastomers as potential tissue engineering materials. Journal of Tissue Engineering and Regenerative Medicine. 

---