Investigation of tissue transglutaminase function in apoptosis

Li, Xiaoling

January 2002

No description available.

571

Cell damage

The development of a pan-centromeric marker to quantify cellular radiation damage in health individuals and in an HIV cohort

Swanson, Rosemary Veronica

13 October 2010

MSc (Med), Molecular Medicine and Haematology, Faculty of Health Sciences, University of the Witwatersrand / INTRODUCTION: Ionising radiation can induce DNA damage, in the form of DNA double strand breaks (DSBs), which the affected cell may or may not be able to repair. Micronuclei are indicators of cytogenetic damage, which result from aneugenic (spontaneous loss of chromosomes) or clastogenic (chromosomal fragments) events. The micronuclei may be centromere-positive (CM+MN) for aneugenic events or centromere-negative (CM–MN) for clastogenic events. A pancentromeric marker would help differentiate between CM+MN and CM–MN, especially important among exposures to very low doses of ionising radiation. METHODOLOGY: Micronucleus assays were performed on blood samples collected from healthy donors and HIV+ donors. The blood samples were irradiated at various doses of ionising radiation. Two methods were used to create a pan-centromeric probe. First, the p82H plasmid, which contains centromere specific α repetitive human DNA sequences, was used. Second, human centromeric sequences were amplified using polymerase chain reaction (PCR). In both cases, the pan-centromeric probe was labelled and hybridised using fluorescent in situ hybridisation (FISH) to micronucleus slide preparations from healthy and HIV+ donors. The slides were scored manually and on an automated system, MetaFer®. RESULTS: The p82H probe did not hybridise to any centromeres when FISH was performed, while the synthetic probe made by means of PCR bound to the centromeres of all chromosomes. Henceforth, all experiments were performed with the synthetic pan-centromeric probe. A dose response study was performed on micronucleus slides from healthy donors, from which significant differences in the number of micronuclei and the percentage of centromere-negative micronuclei could be seen between doses. The HIV study involving HIV+ donors and HIV– controls did not yield any significant differences between the two groups. DISCUSSION & CONCLUSION: Combining the micronucleus assay with the pan-centromeric probe greatly improves its sensitivity. The dose response study corroborated previous work performed by Vral et al (1997). Contrary to what was expected and published (Baeyens et al, 2010), no significant differences were observed between HIV+ and HIV- individuals. Issues, improvements and possible future work are discussed.

cell damage

radiation

Studies of the use of derivatised polycations as potential drug delivery systems to DNA

Besley, Stephen C.

January 1991

The major target of ionising radiation has been determined as cellular DNA. Damage to DNA, as detected at 77K under conditions of direct damage by ESR, is localised on the bases thymine and guanine. This damage leads to single and double strand breaks, precursors of cell death and mutagenesis. In an attempt to intercept the damage at the bases, before formation of strand breaks, the use of polycations as potential drug delivery systems to DNA has been examined. Magnetic resonance techniques have been used to establish that polyamines used are present almost completely as polyammonium cations at pH 7 and to probe the interactions of a number of polycations with DNA. Sodium-NMR was used to investigate the affinity of polyamines, poly- aminothiols and transition-metal complexes for DNA, via sodium ion displacement from the DNA region. It was found that small metal complexes displace a greater number of sodium ions than polyamines of similar charge. Application of the counterion condensation theory led to a model of the counterions existing within a cylinder around the DNA of approximate radius 20A. The mode of interaction of polyammonium cations was studied using proton magnetic resonance. Linewidths, related to the transverse relaxation rate, give information on the motion of compounds close to DNA. Comparison of linewidths in the presence and absence of DNA revealed no significant broadening. This was interpreted as indicative of a loose, electrostatic interaction, not significantly hindering motion of the cations close to DNA, suggesting rapid motion of polyammonium ions along the DNA. The radioprotection of DNA by various transition-metal complexes was studied using ESR. Certain compounds exhibited protection via electron transfer, resulting in a decreased radical yield.

571.45

Radiation-induced cell damage

The effect of herpes simplex virus type 1 on chromosomes of human cells

Peat, D. S.

January 1986

No description available.

572.8

Cell damage by herpes virus

Abiotic stress effects in potato (Solanum tuberosum L.) and sweet potato (Ipomoea batatas [L.] Lam.)

Richardson, Kenneth Vincent Austin

January 2000

No description available.

630

The mechanical properties of sarcolemmal vesicles from rabbit muscle : the effects of internal calcium and membrane active molecules

Nichol, James A.

January 1998

No description available.

612

Modeling the Process of Fabricating Cell-Encapsulated Tissue Scaffolds and the Process-Induced Cell Damage

2013 November 1900

Tissue engineering is an emerging field aimed to combine biological, engineering and material methods to create a biomimetic three dimensional (3D) environment to control cells proliferation and functional tissue formation. In such an artificial structural environment, a scaffold, made from biomaterial(s), plays an essential role by providing a mechanical support and biological guidance platform. Hence, fabrication of tissue scaffolds is of a fundamental importance, yet a challenging task, in tissue engineering. This task becomes more challenging if living cells need to be encapsulated in the scaffolds so as to fabricate scaffolds with structures to mimic the native ones, mainly due to the issue of process-induced cell damage. This research aims to develop novel methods to model the process of fabricating cell-encapsulated scaffolds and process-induced cell damage. Particularly, this research focuses on the scaffold fabrication process based on the dispensing-based rapid prototyping technique - one of the most promising scaffold fabrication methods nowadays, by which a 3D scaffold is fabricated by laying down multiple, precisely formed layers in succession. In the dispensing-based scaffold fabrication process, the flow behavior of biomaterials solution can significantly affect the flow rate of material dispensed, thus the structure of scaffold fabricated. In this research, characterization of flow behavior of materials was studied; and models to represent the flow behaviour and its influence on the scaffold structure were developed. The resultant models were shown able to greatly improve the scaffold fabrication in terms of process parameter determination. If cells are encapsulated in hydrogel for scaffold fabrication, cell density can affect the mechanical properties of hydrogel scaffolds formed. In this research, the influence of cell density on mechanical properties of hydrogel scaffolds was investigated. Furthermore, finite element analysis (FEA) of mechanical properties of scaffolds with varying cell densities was performed.The results show that the local stress and strain energy on cells varies at different cell densities. The method developed may greatly facilitate hydrogel scaffolds design to minimize cell damage in scaffold and promote tissue regeneration. . In the cell-encapsulated scaffold fabrication process, cells inevitably suffer from mechanical forces and other process-induced hazards. In such a harsh environment, cells deform and may be injured, even damaged due to mechanical breakage of cell membrane. In this research, three primary physical variables: shear stress, exposure time, and temperature were examined and investigated with regard to their effects on cell damage. Cell damage laws through the development phenomenal models and computational fluidic dynamic (CFD) models were established; and their applications to the cell-encapsulated scaffold fabrication process were pursued. The results obtained show these models and modeling methods not only allow one to optimize process parameters to preserve cell viability but also provide a novel strategy to probe cell damage mechanism in microscopic view.

Fabrication of alginate hydrogel scaffolds and cell viability in calcium-crosslinked alginate hydrogel

Cao, Ning

03 August 2011

Tissue-engineering (TE) is one of the most innovative approaches for tackling many diseases and body parts that need to be replaced, by developing artificial tissues and organs. For this, tissue scaffolds play an important role in various TE applications. A tissue scaffold is a 3D (3D) structure with interconnected pore networks and used to facilitate cell growth and transport of nutrients and wastes while degrading gradually itself. Many fabrication techniques have been developed recently for incorporating living cells into the scaffold fabrication process and among them; dispensing-based rapid prototyping techniques have been drawn considerable attention due to its fast and efficient material processing. This research is aimed at conducting a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. Dispensing-based polymer deposition system was used to fabricate 3D porous hydrogel scaffolds. Sodium alginate was chosen and used as a scaffolding biomaterial. The influences of fabrication process parameters were studied. With knowledge and information gained from this study, 3D hydrogel scaffolds were successfully fabricated. Calcium chloride was employed as crosslinker in order to form hydrogels from alginate solution. The mechanical properties of formed hydrogels were characterized and examined by means of compressive tests. The influences of reagent concentrations, gelation time, and gelation type were studied. A post-fabrication treatment was used and characterized in terms of strengthening the hydrogels formed. In addition, the influence of calcium ions used as crosslinker on cell viability and proliferation during and after the dispensing fabrication process was examined and so was the influence of concentration of calcium solutions and exposing time in both media and alginate hydrogel. The study also showed that the density of encapsulated cells could affect the viscosity of alginate solution. In summary, this thesis presents a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. The results obtained regarding the influence of various factors on the cell viability and scaffold fabrication would form the basis and rational to continue research on fabricating 3D cell-encapsulated scaffolds for specific applications.

ionic crosslinking

cell damage

alginate

scaffold

hydrogel

tissue engineering

Fabrication of alginate hydrogel scaffolds and cell viability in calcium-crosslinked alginate hydrogel

Cao, Ning

03 August 2011

Tissue-engineering (TE) is one of the most innovative approaches for tackling many diseases and body parts that need to be replaced, by developing artificial tissues and organs. For this, tissue scaffolds play an important role in various TE applications. A tissue scaffold is a 3D (3D) structure with interconnected pore networks and used to facilitate cell growth and transport of nutrients and wastes while degrading gradually itself. Many fabrication techniques have been developed recently for incorporating living cells into the scaffold fabrication process and among them; dispensing-based rapid prototyping techniques have been drawn considerable attention due to its fast and efficient material processing. This research is aimed at conducting a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. Dispensing-based polymer deposition system was used to fabricate 3D porous hydrogel scaffolds. Sodium alginate was chosen and used as a scaffolding biomaterial. The influences of fabrication process parameters were studied. With knowledge and information gained from this study, 3D hydrogel scaffolds were successfully fabricated. Calcium chloride was employed as crosslinker in order to form hydrogels from alginate solution. The mechanical properties of formed hydrogels were characterized and examined by means of compressive tests. The influences of reagent concentrations, gelation time, and gelation type were studied. A post-fabrication treatment was used and characterized in terms of strengthening the hydrogels formed. In addition, the influence of calcium ions used as crosslinker on cell viability and proliferation during and after the dispensing fabrication process was examined and so was the influence of concentration of calcium solutions and exposing time in both media and alginate hydrogel. The study also showed that the density of encapsulated cells could affect the viscosity of alginate solution. In summary, this thesis presents a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. The results obtained regarding the influence of various factors on the cell viability and scaffold fabrication would form the basis and rational to continue research on fabricating 3D cell-encapsulated scaffolds for specific applications.

ionic crosslinking

cell damage

alginate

scaffold

hydrogel

tissue engineering

Cell Damage Mechanisms and Stress Response in Animal Cell Culture

Berdugo, Claudia

25 August 2010

No description available.

Chemical Engineering

Mammalian cell culture

hydrodynamic stress

cell damage

shear stress

flow cytometry

CHO

THP1

bioreactors