Blasenaugmentation mit Hilfe eines biokompatiblen Materials im Rattenmodell / Bladder augmentation with Lyoplant® : First experimental results in rats

Winde, Friederike

January 2018

In der Studie dieser Dissertation wird untersucht, ob das biokompatible Kollagennetz Lyoplant® (B.Braun, Deutschland) ein geeignetes Biomaterial zur Harnblasenaugmentation ist. Es wurden 16 Wistar Ratten ein Lyoplant® -Netz in die Harnblasen implantiert. Nach sechs Wochen lang täglicher Visite wurden die Harnblasen explantiert und mikroskopisch, sowie immunhistologisch aufgearbeitet. Es zeigte sich eine Epithelialisierung und die Bildung von Bindegewebe, außerdem wenig Entzündungszellen, sodass Lyoplant® ein gut verträgliches Material zur Blasenaugmentation im Kleintiermodell ist. / In our study, the biocompatible collagen mesh Lyoplant® (B.Braun, Germany) was tested as a suitable material for bladder augmentation in a trial with 16 rats. The material seem to be immunocompetent. The transplant acceptance is based on the remodelling process, initiated by neovascularisation. Lyoplant® is converted into epithelial and connective tissue.

Ersatzblase

Biomaterial

ddc:617

Physical Characterization of Fibres Produced from Recombinant Vimentin

Pinto, Nicole

12 December 2012

Recent attention has focused on the use of renewable resources as an alternative to petroleum-based polymers. Fudge et al. (2010) demonstrated that hagfish slime threads, which are composed of “keratin-like” intermediate filament (IF) proteins undergo an α→β transition when strained and when exposed to glutaraldehyde, mechanical properties further improved. Negishi et al. (2012) showed that fibres produced from solubilized hagfish slime threads did not possess comparable mechanical characteristics to native slime threads and were unable to assemble into 10 nm filaments. In this study, fibres were produced from solubilized recombinant vimentin protein and assembled vimentin filaments. Solubilized protein fibres did not display mechanical properties as impressive as fibres made from filaments assembled in the presence magnesium and glutaraldehyde. Additionally, X-ray diffraction analysis of fibres cross-linked with magnesium showed an α→β transition when draw-processed. These data show that fibres produced using IFs can potentially be used for production of sustainable protein polymers.

Clinical implications of infection, encrustation and fracture of polyurethane-based ureteral stents

Bonner, Michael Charles

January 1995

No description available.

610

Biomaterial; Urolithiasis

Analysis of nanoparticle dispersion, biological interactions and drug incorporation of polyurethane nanocomposite materials

Farrugia, Brooke Louise, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW

January 2010

The use of polymer nanocomposites (NCs) in industrial applications has received growing attention over the past decade due to their improved mechanical properties. However, little work has been reported which analyses the efficacy of NCs in biological applications, including drug delivery systems and implantable materials. This thesis examines the effect of the chemistry of the organic modifier (OM) on the structure and biological performance of poly(ether)urethane NCs (PUNCs) and the influence of the method of drug incorporation on interactions between drug and NC. Organically modified silicates (OMS) were prepared using OMs varying in terminal functionality and alkyl chain length. PUNCs were solvent cast containing 1 and 3wt% OMS and particle dispersion analysed using X-ray diffraction and transmission electron microscopy. Findings revealed that use of an OM with methyl terminal, dodecylamine (12CH3), resulted in superior dispersion of OMS compared with a carboxyl terminated OM, aminododecanoic acid (12COOH), of equivalent alkyl chain length. This is believed to result from increased self interaction of 12COOH compared with 12CH3. Additionally, increased alkyl chain length was shown to improve NC dispersion with a chain length of sixteen units resulting in the optimum dispersion with a partially exfoliated NC structure. Analysis of cellular interactions with the PUNCs revealed a significant difference in both fibroblast and platelet adhesion to NCs incorporating 12CH3 compared with 12COOH. Surface analysis using ToF-SIMS demonstrated the presence of 12CH3 fragments on the NC surface supporting the hypothesis that surface expressed OMs alter cellular interactions with the NC. Altering the alkyl chain length also affected cellular interaction with an alkyl chain length of twelve units or greater, substantially reducing fibroblast adhesion without affecting cell growth inhibition or viability. Incorporation of a model drug, crystal violet, into the PUNCs demonstrated a lower degree of disruption to OMS dispersion when loaded post NC fabrication compared with pre fabrication. This is believed to result from interactions between the drug and NC constituents which also impacted on drug release from the NC system. Results show PUNC properties and biological interactions can be modulated through OM variation and fabrication method, thus showing potential for use in biomedical applications.

Biomaterial

Polyurethane

Nanocomposite

Analysis of nanoparticle dispersion, biological interactions and drug incorporation of polyurethane nanocomposite materials

Farrugia, Brooke Louise, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW

January 2010

The use of polymer nanocomposites (NCs) in industrial applications has received growing attention over the past decade due to their improved mechanical properties. However, little work has been reported which analyses the efficacy of NCs in biological applications, including drug delivery systems and implantable materials. This thesis examines the effect of the chemistry of the organic modifier (OM) on the structure and biological performance of poly(ether)urethane NCs (PUNCs) and the influence of the method of drug incorporation on interactions between drug and NC. Organically modified silicates (OMS) were prepared using OMs varying in terminal functionality and alkyl chain length. PUNCs were solvent cast containing 1 and 3wt% OMS and particle dispersion analysed using X-ray diffraction and transmission electron microscopy. Findings revealed that use of an OM with methyl terminal, dodecylamine (12CH3), resulted in superior dispersion of OMS compared with a carboxyl terminated OM, aminododecanoic acid (12COOH), of equivalent alkyl chain length. This is believed to result from increased self interaction of 12COOH compared with 12CH3. Additionally, increased alkyl chain length was shown to improve NC dispersion with a chain length of sixteen units resulting in the optimum dispersion with a partially exfoliated NC structure. Analysis of cellular interactions with the PUNCs revealed a significant difference in both fibroblast and platelet adhesion to NCs incorporating 12CH3 compared with 12COOH. Surface analysis using ToF-SIMS demonstrated the presence of 12CH3 fragments on the NC surface supporting the hypothesis that surface expressed OMs alter cellular interactions with the NC. Altering the alkyl chain length also affected cellular interaction with an alkyl chain length of twelve units or greater, substantially reducing fibroblast adhesion without affecting cell growth inhibition or viability. Incorporation of a model drug, crystal violet, into the PUNCs demonstrated a lower degree of disruption to OMS dispersion when loaded post NC fabrication compared with pre fabrication. This is believed to result from interactions between the drug and NC constituents which also impacted on drug release from the NC system. Results show PUNC properties and biological interactions can be modulated through OM variation and fabrication method, thus showing potential for use in biomedical applications.

Biomaterial

Polyurethane

Nanocomposite

Blood protein coated model biomaterials : preparation, and cell and tissue response /

Jansson, Eva,

January 2003

Diss. (sammanfattning) Linköping : Univ., 2003. / Härtill 6 uppsatser.

Biomolecular interactions with porous silicon /

Karlsson, Linda,

January 2003

Diss. (sammanfattning) Linköping : Univ., 2003.

Investigation of incompatibility reactions caused by biomaterials in contact with whole blood using a new in vitro model /

Hong, Jaan,

January 1900

Diss. (sammanfattning) Uppsala : Univ., 2001. / Härtill 4 uppsatser.

BActerial SYnthetisized Cellulose - BASYC - Qualifizierung eines für die Mikrochirurgie neuen Biomaterials /

Marsch, Silvia.

January 2004

Universiẗat, Diss.--Jena, 2004.

Biomaterial. Cellulose. Mikrochirurgie.

Adhäsion und Differenzierung humaner mesenchymaler Progenitorzellen auf Polyethylen-Glykol-beschichteten und durch lineare und zyklische RGD-Peptide funktionalisierten Oberflächen

Engelhard, Erika,

January 2006

Ulm, Univ. Diss., 2006.