Blended nanostructured degradable mesh with endometrial mesenchymal stem cells promotes tissue integration and anti-inflammatory response in vivo for pelvic floor application
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Title |
Blended nanostructured degradable mesh with endometrial mesenchymal stem cells promotes tissue integration and anti-inflammatory response in vivo for pelvic floor application
Not Available |
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Creator |
S. Mukherjee
S. Darzi A. Rosamilia V. Kadam Y. Truong J. A. Werkmeister, C. E. Gargett |
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Subject |
Electrospinning
Mesenchymal Stem Cells Tissue Engineering Foreign Body Response Pelvic Organ Prolapse iomaterials |
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Description |
Not Available
The current urogynaecological clinical meshes trigger unfavourable foreign body response which leads to graft failure in the long term. To overcome the present challenge we applied a tissue engineering strategy using endometrial SUSD2+ Mesenchymal stem cells (eMSCs) with high regenerative properties. This study delves deeper into foreign body response to SUSD2+ eMSC based degradable PLACL/Gelatin nanofiber meshes using a mice model targeted at understanding immunomodulation and mesh integration in the long term. Delivery of cells with nanofiber mesh provides a unique topography that enables entrapment of therapeutic cells for upto 6 weeks that promotes substantial cellular infiltration of host anti-inflammatory macrophages. As a result, degradation rate and tissue integration are highly impacted by eMSCs, revealing an unexpected level of implant integration over 6 weeks in vivo. From a clinical perspective, such immunomodulation may aid in overcoming the current challenges and provide an alternative to an unmet women’s urogynaecological health need. National Health and Medical Research Council (NHMRC), Australia CSIRO, Clayton Australia |
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Date |
2020-09-10T03:19:05Z
2020-09-10T03:19:05Z 2018-12-04 |
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Type |
Research Paper
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Identifier |
Mukherjee, S., Darzi, S., Rosamilia, A., Kadam, V., Truong, Y., Werkmeister, J. A., & Gargett, C. E. (2018). Blended nanostructured degradable mesh with endometrial mesenchymal stem cells promotes tissue integration and anti-inflammatory response in vivo for pelvic floor application. Biomacromolecules, 20(1), 454-468.
Not Available http://krishi.icar.gov.in/jspui/handle/123456789/41104 |
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Language |
English
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Relation |
Not Available;
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Publisher |
ACS Publications
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