Microencapsulated Stem Cells for Tissue Repairing: Implications in Cell-Based Myocardial Therapy

Paul, Arghya; Ge, Yin; Prakash, Satya; Shum‐Tim, Dominique

doi:10.2217/rme.09.43

Cited by 57 publications

(42 citation statements)

References 91 publications

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“…1,40 Direct intramyocardial delivery by injecting microencapsulated marrow stromal cells to the peri-infarct region of acutely infarcted heart can be of immense potential as shown by our recent preliminary preclinical data. 28 It shows that the retention of cells can be increased by approximately four times by using microcapsules in comparison to free cells. Thus, in order to develop a more advanced delivery system for myocardial transplantation, we have designed these smooth, spherical and much more resilient PEG integrated polymeric microcapsules with a diameter of around 400 lm encapsulating an average of 80 cells per capsule.…”

Section: Discussionmentioning

confidence: 96%

Investigation on PEG Integrated Alginate–Chitosan Microcapsules for Myocardial Therapy Using Marrow Stem Cells Genetically Modified by Recombinant Baculovirus

Paul

Shum‐Tim

Prakash

2010

Cardiovasc Eng Tech

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Bone marrow derived mesenchymal stem cell (BMSCs) therapy can significantly improve cardiac ventricular function following ischemic injury. Their potential can be further enhanced by using genetically modified cells, overexpressing certain therapeutic biomolecules. However, such therapy is limited by low efficiency of transplantation of the cells, secreting inadequate therapeutic proteins. To address these issues, we developed recombinant baculoviruses to genetically modify the BMSCs and investigated the potential of using polyethylene glycol (PEG) integrated alginate-chitosan microcapsules (AC) for efficient myocardial transplantation. The data indicates that the cells encapsulated in AC-PEG microcapsules grew rapidly from 80 cells per capsule to above 100 cells per capsule within a week, reaching a confluency of average 110 cells by day 9 of encapsulation. The microcapsules proved superior to commonly used AC microcapsules in terms of immune protection. After 11 days of co-culture of the encapsulated cells with highly confluent lymphocytes, the viable cell population in AC-PEG microcapsules was reduced by only 20%, whereas in AC microcapsules it was reduced to more than 50%. AC-PEG microcapsules also had significantly higher mechanical (65 vs. 10%) and osmotic (92 vs. 52%) stability than commonly used AC microcapsules as seen after 2 h of external stresses. The entrapped genetically modified cells showed highest transgene expression on day 1, which was gradually reduced to 48% after 1 week and to 14% after 2 weeks. This expression pattern was also dependant on initial viral incubation time, with 8 h incubation being the optimum. The encapsulated cells, transduced with baculovirus, also retained their inherent potential to differentiate into multiple lineages. Because of the above characteristics, the baculovirus transduced microencapsulated BMSCs have immense potential in myocardial cell-based gene therapy, although preclinical studies are needed to be done to establish their functional benefits on myocardial implantation.

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Section: Discussionmentioning

confidence: 96%

Investigation on PEG Integrated Alginate–Chitosan Microcapsules for Myocardial Therapy Using Marrow Stem Cells Genetically Modified by Recombinant Baculovirus

Paul

Shum‐Tim

Prakash

2010

Cardiovasc Eng Tech

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“…Alginate is an unbranched natural copolymer composed of β-D-mannuronate (M) and α-L-guluronate (G), linked together by 1,4 bonds (Garbayo et al, 2002;Bajpai and Sharma, 2004). Due to its relative stability, biocompatibility, adjustable porosity and simplicity of use, alginate is thus a biomaterial of choice when it comes to entrapping cells (Garbayo et al, 2002;Zmora et al, 2002;David et al, 2004a;De Vos et al, 2006;Zimmermann et al, 2007;Wikstrom et al, 2008), to cell therapy (Chang, 2005;Paul et al, 2009) or to being used in medical devices (Ueyama et al, 2002;Orive et al, 2004;Gao et al, 2005;De Vos et al, 2006;Orive et al, 2006;Wikstrom et al, 2008). Some of these studies were conducted with hepatocytes that were either encapsulated within alginate beads (Selden et al, 1999;David et al, 2004b;Gao et al, 2005;Kinasiewicz et al, 2007;Kinasiewicz et al, 2008) or capsules (Canaple et al, 2001;Orive et al, 2004;Haque et al, 2005), or seeded within alginate scaffolds (Zmora et al, 2002;Seo et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Impact of alginate type and bead diameter on mass transfers and the metabolic activities of encapsulated C3A cells in bioartificial liver applications

Gautier

Carpentier²,

Dufresne³

et al. 2011

eCM

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Liver-assist devices have been developed in the last few decades to support patients with liver failure on the road to recovery or transplantation. Fluidised bed bio-artificial livers -where liver cells are encapsulated within alginate beads -appear to be a valuable alternative to hollow fibre devices for improving mass transfers and enhancing treatment efficacy. This approach nevertheless deserves optimization in terms of bead production. The aim of this study was to investigate the impact of alginate type and of two bead diameters (1000 μm and 600 μm) on mass transfers within beads and on the biological functions of encapsulated C3A cells.After assessing the effect of the encapsulation process on bead quality, we investigated cell viability and metabolic activities (ammonia, albumin, α-foetoprotein synthesis and glucose consumption). They were successfully maintained over 48 h within fluidised bed bioreactors, independently of alginate type and bead diameter. Mass transfers were not significantly influenced by the latter parameters. Finally, suggestions are made for improving the entrapment process as a means of enhancing the treatment efficiency of the fluidised bed bioartificial liver.

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“…For that reason, and from our study results, the portal vein should be regarded as a priority route for UCB-MSC treatment of liver cirrhosis, with careful considerations to eliminate the risk of bleeding and damage to the recipient organ (Paul et al, 2009). …”

Section: Discussionmentioning

confidence: 84%

Transplantation of umbilical cord blood-derived mesenchymal stem cells to treat liver cirrhosis in mice: a comparison of tail and portal vein injection

et al. 2017

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Introduction: To date, there have been many studies indicating the positive effects of stem cells on treating liver cirrhosis. In this study, we used umbilical cord blood-derived mesenchymal stem cells (UCB-MSCs) for treatment in a mouse model of liver cirrhosis. Specifically, we determined and compared the effectiveness of two methods of MSC injection (tail vein versus portal vein). Methods: Liver cirrhosis in male Swiss mice (of age approximately 11 weeks or under) was induced by administration of carbon tetrachloride (CCl 4 ; 1 ml/kg). One million UCB-MSCs were then transplanted into cirrhotic mice via the portal vein or tail vein. After 21 days, blood samples were collected for measurement of transaminase, bilirubin and albumin. The expression of fibrosis-associated genes, specifically procollagen -alpha 1 and integrin -beta1, were assessed using quantitative RT-PCR. The histopathology of the specimens was also evaluated using hematoxylin/ eosin, Masson trichrome staining, and immunohistochemistry using collagen type 1 and alpha-SMA antibodies. Results: After 21 days, cirrhotic mice treated with UCB-MSCs showed recovery of bilirubin index, increase of liver albumin synthesis, inhibition of fibrosis-related gene expression (e.g. procollagen -alpha 1 and integrin -beta1), and remodeling of liver histology. From comparison of the different routes of transplantation, UCB-portal route was significantly more effective than UCB-tail route at reducing aspartate transaminase (AST) activity and bilirubin index (P<0.05), and inhibiting procollagen -alpha 1 and integrin -beta1 expression (P<0.05). UCB-MSCs from both transfusion routes showed accelerated improvement of liver histopathology.

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Microencapsulated Stem Cells for Tissue Repairing: Implications in Cell-Based Myocardial Therapy

Cited by 57 publications

References 91 publications

Investigation on PEG Integrated Alginate–Chitosan Microcapsules for Myocardial Therapy Using Marrow Stem Cells Genetically Modified by Recombinant Baculovirus

Investigation on PEG Integrated Alginate–Chitosan Microcapsules for Myocardial Therapy Using Marrow Stem Cells Genetically Modified by Recombinant Baculovirus

Impact of alginate type and bead diameter on mass transfers and the metabolic activities of encapsulated C3A cells in bioartificial liver applications

Transplantation of umbilical cord blood-derived mesenchymal stem cells to treat liver cirrhosis in mice: a comparison of tail and portal vein injection

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