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Showing 2 results for Proliferation
Mohammad Nabiouni, Elham Havizi, Azar Chavoshian, Somayeh Bahramzadeh, Mahmood Hashemitabar,
Volume 26, Issue 2 (6-2016)
Abstract
Background: Recent advances in directed differentiation of pancreatic stem cells offers potential to the development of replacement therapy for diabetic patients. However, the existing differentiation protocols are complex, time-consuming, and costly; thus there is a need for alternative protocols. Today, co-culturing with pancreatic islets is apparently a promising protocol for producing beta cells. Furthermore, we need keep islets viable in vitro for extended time periods.
Materials and methods: We maintained isolated pancreatic islets obtained from the mouse pancreas in tissue culture for 2 weeks, after which we studied the viability, proliferation and morphology of the islets. Pancreatic islets were isolated from overnight-fasted male NMRI mice by Lacy and Kostianovsky modified collagenase digestion method and islets were tested for their specificity by dithizone (DTZ) staining. Also, islet cell viability was tested by MTT assay.
Results: Our results showed that viable pancreatic islets can be isolated from the pancreas of adult mice and maintained in tissue culture for at least 1 week, without loss of the specific functions of the cells. Cell viability of pancreatic islets was decreased after one week and also, the cell number decreased over time. Cell viability and cell number were decrease if cells were incubated for long time.
Conclusion: It remains to be established whether such islets will survive and remain functionally competent after co culturing. Survey of viability of pancreatic islets is necessary in in vitro, because these were used for cell therapy for diabetes.
Keywords: Survival, Proliferation, Pancreatic islets, Culture, MTT, NMRI.
Sahar Abbasi Geravand, Ramin Khajavi, Mohammad Karim Rahimi, Manouchehr Shamsini Ghiyasvand, Amin Meftahi,
Volume 32, Issue 1 (3-2022)
Abstract
Background: Nanomicrobial cellulose is an important biopolymer with a three-dimensional structure that is produced by some microorganisms and has been widely used in medicine. One of the unique properties of microbial cellulose is its very high water absorption, which can be used to produce modern wound dressings. But after drying, it’s three-dimensional structure collapses and the amount of water reabsorption decreases. Accordingly, the aim of this project was to preserve the three-dimensional structure of nanomicrobial cellulose by networking it and improving the water reabsorption properties of this biopolymer. In addition, the cell viability, proliferation, and cell growth of the modified structure and untreated microbial cellulose were also studied.
Materials and methods: In this study, microbial cellulose was produced, purified, and neutralized using stationary culture. The samples were then treated with different concentrations of citric acid/sodium hypophosphite and crosslinked. Finally, the characteristics of treated and raw samples were studied by various tests including ATR-FTIR, MTT, SEM, water absorption and in vitro and in vitro tests.
Results: According to the results, it was found that the cross-linking operation prevents the collapse of the structure and not only does not cause toxicity, but in addition to increasing water uptake, it also increases viability, adhesion, and cell proliferation in the modified cellulose.
Conclusion: Cross-linked nanomicrobial cellulose has high potential as a modern wound dressing.
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