References - Natural Polymers, Biopolymers, Biomaterials, and Their Composites, Blends, and IPNs

Biomedical Engineering Reference

In-Depth Information

Pieper, J. S., Oosterhol, A., Dijakstra, P. J.,

Veerkamp, J. H., and van Kuppevelt, T. H.

(1999). Preparation and characterization of po-

rous cross-linked collagenous matrices contain-

ing bioavailable chondroitin sulphate. Biomate-

rials 20 , 847-858.

Pietrucha, K. (1991). New collagen implant as

dural substitute. Biomaterials 12 , 320-323.

Pietrucha, K. (2005). Changes in denaturation

and rheological properties of collagen-hyaluron-

ic acid scaffolds as a result of temperature de-

pendencies. International Journal of Biological

Macromolecules 36 , 299-304.

Pietrucha, K. (2007). Some biological and ther-

mo-analytical studies of cross-linked collagen

sponges. Med. and Biol. Eng. and Comp. (JIF-

MBE) 14 , 3369-3372.

Pietrucha, K. (2010a). Role of a new composite

collagen-based material in the surgical treatment

of dysraphic defects of the central nervous sys-

tem in children. http://www.bit-ibio.com .

Pietrucha, K. (2010b). Biodegradable collagen-

based 3-d structure as a potential scaffolds for

tissue engineering. http://www.biopolymers.

macromol.in.

Pietrucha, K. and Banas M. (2009). Diffusive

properties of hybrid collagen derivative hydro-

gels for medical applications. www.hybridmate-

rialsconference. com.

Pietrucha, K. and Banas, M. (2010). The effect

of different methods of cross-linking of fish col-

lagen on some its properties. http://www. bio-

polymers.macromol.in.

Pietrucha, K. and Marzec, E. (2005) . Dielectric

properties of the collagen-glycosaminoglycans

scaffolds in the temperature range of thermal de-

composition. Biophysical Chemistry 118 , 51-56.

Pietrucha, K. and Marzec, E. (2007). Character-

ization of electrically conductive biodegradable

materials for potential medical application. Med-

ical and Biological Engineering and Computing

(JIFMBE) 14 , 3376-3378.

Pietrucha, K. and Polis, L. (2009). New collagen

implant as a dura mater of the brain and spinal

cord. http://www.iiis.org/CDs2009/CD2009SCI/

BMIC2009/PapersPdf/B085TK.pdf.

Pietrucha, K., Polis, L., and Bidziński, J. (2000).

Long-term clinical experiences with a new dural

substitute. Molecular Crystals and Liquid Cry-

stals 354 , 243-248.

Pietrucha, K. and Verne, S. (2010). Synthesis and

characterization of a new generation of hydro-

gels for biomedical applications. IFMBE Pro-

ceedings ISBN 978-3-642-03899-0, 25/10 World

Congress on Medical Physics and Biological

Engineering WC2009, 7-12 September, 2009,

Munich, Germany. Biomaterials, Cellular and

Tissue Engineering, Artificial Organs. O. Dos-

sel and C. Schlegel (Eds.). Springer, Germany,

pp. 1-4.

Polis, L., Pietrucha, K., Nowosławska, E., Szy-

mański, W., and Zakrzewski, K. (1993). Use of

a new collagen implant as a dural substitute in

child neurosurgery with special regards to the

treatment of dysraphic defects in the central

nervous system. Polish Journal of Neurology

and Neurosurgery 27 , 323-326.

Powell, H. M., Supp, D. M., and Boyce, S. T.

(2008). Influence of electrospun collagen on

wound contraction of engineered skin substi-

tutes. Biomaterials 29 , 834-843.

Tanaka, E. M. and Ferretti, P. (2009). Consider-

ing the evolution of regeneration in the central

nervous system. Nature Reviews/Neuroscience

10 , 713-723.

Thomas, V., Dean, D. R., Jose, M. V., Mathew,

B., Chowdhury, S., and Vohra, Y. K. (2007).

Nanostructured biocomposite scaffolds based on

collagen coelectrospun with nanohydroxyapa-

tite. Biomacromolecules 8 , 631-637.

Vin, F., Teot, L., and Meaume, S. (2002). The

healing properties of Promogran in venous leg

ulcers. Journal of Wound Care 11 , 335.

Wang, X., Zhang, J., Chen, H., and Wang, Q.

(2009). Preparation and Characterization of Col-

lagen-Based Composite Conduit for Peripheral

Nerve Regeneration. Journal of Applied Poly-

mers Science 112 , 3652-3662.

Wen, X., Shi, D., and Zhang, N. (2005). Applica-

tions of Nanotechnology in Tissue Engineering.

In Handbook of Nanostructured Biomaterials

and Their Applications in Nanobiotechnology .

H. S. Nalwa (Ed.). American Scientific Publish-

ers, California, pp. 1 , 1-23.

Wess, T. J. (2008). Collagen Fibrillar Struc-

ture and Hierarchies. In Collagen Structure

and Mechanics . P. Fratzl (Ed.), Springer

Natural Polymers, Biopolymers, Biomaterials, and Their Composites, Blends, and IPNs

Search WWH ::

Custom Search

Home