Effects of Н2О2-plasma processing on properties of cellular scaffolds made of «Bioplastotan»resorbing polyesters
- Authors: Nikolaeva ED1, Goncharov DB2, Shishatskaya EI2
-
Affiliations:
- Institute of Biophysics, Siberian branch of the RAS, Krasnoyarsk
- Siberian Federal university, Krasnoyarsk
- Issue: Vol 6, No 2 (2011)
- Pages: 65-70
- Section: Articles
- URL: https://genescells.ru/2313-1829/article/view/121666
- DOI: https://doi.org/10.23868/gc121666
- ID: 121666
Cite item
Open Access
Access granted
Subscription or Fee Access
Abstract
Produced from «Bioplastotan» resorbing polyesters (linear
polyesters of hydroxyl derivatives alkanoic acids) scaffolds for
cell culturing such as films, pressed 3-D forms and nonwoven
fabric from ultrathin fibers are characterized. Two types of
polymers - a homopolymer of the 3-hydroxybutyric acid and
a copolymer formed by monomers of the 3-hydroxybutyric
and 3-hydroxyvalerianic acids are studied. Surface properties
of developed polymer scaffolds, sterilized with autoclaving
and Н2О2-plasma processing are compared. It is shown that
plasma has beneficial effects resulting in decrease of the
watering contact angle and increase of surface hydrophilic
properties. Positive effects of Н2О2-plasma processing
of scaffold surface on culturing cell adhesion and viability
compared with autoclaving sterilization is demonstrated on
NIH 3T3 line fibroblast culturing.
polyesters of hydroxyl derivatives alkanoic acids) scaffolds for
cell culturing such as films, pressed 3-D forms and nonwoven
fabric from ultrathin fibers are characterized. Two types of
polymers - a homopolymer of the 3-hydroxybutyric acid and
a copolymer formed by monomers of the 3-hydroxybutyric
and 3-hydroxyvalerianic acids are studied. Surface properties
of developed polymer scaffolds, sterilized with autoclaving
and Н2О2-plasma processing are compared. It is shown that
plasma has beneficial effects resulting in decrease of the
watering contact angle and increase of surface hydrophilic
properties. Positive effects of Н2О2-plasma processing
of scaffold surface on culturing cell adhesion and viability
compared with autoclaving sterilization is demonstrated on
NIH 3T3 line fibroblast culturing.
About the authors
E D Nikolaeva
Institute of Biophysics, Siberian branch of the RAS, KrasnoyarskInstitute of Biophysics, Siberian branch of the RAS, Krasnoyarsk
D B Goncharov
Siberian Federal university, KrasnoyarskSiberian Federal university, Krasnoyarsk
E I Shishatskaya
Siberian Federal university, KrasnoyarskSiberian Federal university, Krasnoyarsk
References
- Nitschke M., Schmack G., Janke A. et al. Low pressure plasma treatment of poly(3-hydrobutyrate): toward tailored polymer surfaces for tissue engineering scaffolds. J. Biomed. Mater. Res. 2001; 59: 632-8.
- Де Жен П.Ж. Смачивание: Статика и динамика. Успехи фи- зических наук 1987; 151: 619-81
- Cheng G., Cai Z., Wang L. Biocompatibility and biodegradability of poly(hydroxybutyrate)/(poly(ethylene glycol) blend films. J. Mater. Sci. Mater. Med. 2003; 14: 1073-8.
- Волова Т.Г., Калачева Г.С. Способ получения полимера -оксимасляной кислоты. Патент РФ 2051967. 1996 Янв 10.
- Волова Т.Г., Калачева Г.С., Константинова В.М. Способ получения гетерополимера -оксимасляной и -оксивалериановой кислот. Патент РФ 2051968. 1996 Янв 10.
- Шишацкая Е.И. Биосовместимые и функциональные свой- ства гибридного композита полигидроксибутират/гидроксиапатит. Вестник Института трансплантологии и искусственных органов 2006; 3: 34-8.
- Wang M., Chen L.J., Weng J. et al. Manufacture and evaluation of bioactive and biodegradable materials and scaffolds for tissue engineering. J. Mater. Sci. Mater. Med. 2002; 12: 856-60.
- Хенч Л., Джонс Д. Биоматериалы, искусственные органы и инжиниринг тканей. М.: Техносфера; 2007.
- Штильман М.И. Полимеры медико-биологического назначе- ния. М.: Академкнига; 2006.
- Волова Т.Г., Севастьянов В.И., Шишацкая Е.И. Полиоксиал- каноаты - биоразрушаемые полимеры для медицины. Красноярск: Платина; 2006.
- Волова Т.Г., Некрасов Ю.П., Шишацкая Е.И. и др. Характери- стика изделий на основе полиоксиалканоатов - разрушаемых при- родных полиэфиров. Пластические массы 2003; 3: 6-8.
- Volova T.G., Shishatskaya E.I., Sevastianov V.I. et al. Results of biomedical investigations of PHB and PHB/PHV fibers. Biochemical Eng. J. 2003; 16: 125-33.
- Волова Т.Г., Шишацкая Е.И., Гордеев С.А. Характеристика ультратонких волокон, полученных электростатическим формова- нием термопластичного полиэфира [поли(гидроксибутирата/гидро- сивалерата)]. Перспективные материалы 2006; 3: 25-9.
- Шишацкая Е.И., Горева А. Микрочастицы из биорарушаемого полиоксибутирата в качестве матрикса для депонирования рубоми- цина. Перспективные материалы 2006; 4: 65-70.
- Шишацкая Е.И., Еремеев А.В., Гительзон И.И. и др. Иссле- дование цитотоксичности полиоксиалканоатов в культуре животных клеток. Доклады РАН 2000; 374: 561-4.
- Shishatskaya E.I., Volova T.G. A comparative investigation of biodegradable polyhydroxyalkanoate films as matrices for in vitro cell cultures. J. Mater. Sci. Mater. Med. 2004; 15: 915-23.
- Shishatskaya E.I., Chlusov I.A., Volova T.G. A hybrid PHAhydroxyapatite composite for biomedical application: production and investigation. J. Biomat. Sci. Polymer. Edn. 2006; 17: 481-З.
- Торговая марка «БИОПЛАСТОТАН». Регистрационное свиде- тельство № 315652 Федерального института патентной эксперти- зы. 2006 Фев 15.
- Севастьянов В.И., Егорова В.А., Немец Е.А. и др. Биодегра- дируемый биополимерный материал ЭластоПОБ™ для клеточной трансплантации. Перспективные материалы 2004; 3: 35-41.
- Tesema Y., Raghavan D., Stubbs J. Bone cell viability on collagen immobilizated poly(3- hydroxybutyrate-co-3-hydroxyvalerate) membrane effect of surface chemistry. J. Appl. Polymer Sci. 2004; 93: 2445-53.
- Hu S.G., Jou C.H., Yang M.C. Protein adsorption, fibroblast activity and antibacterial properties of poly(3- hydroxybutyrate-co-3- hydroxyvalerate acid) grafted with chitosan and chitooligasaccharide after immobilized with hualuronic acid. Biomaterials 2003; 24: 2685-93.
- Grondahl L., Chandler-Temple A., Trau M. Polymeric grafting of acrylic axcid onto poly(3-hydroxybutyrate-co-3-hydroxyvalerate): surface functionalization for tissue engineering application. Biomacromol. 2005; 6: 2197-203.
- Slabko V.V., Volova T.G., Shoshatskaya E.I. et al. Surface modification of bioresorbable polymer scaffolds by laser treatment. Biophysics. 2010; 55: 234-8.
- Qu X.H., Wu Q., Liang J., et al. Enchanced vascular-related cellular affinity on surface modified copolyester of 3-hydroxybutyrate and 3-hydroxyhexanoate (PHBHHx). Biomaterials 2005; 26: 6991-7001.
Supplementary files
