Literature DB >> 21210760

Prospects of induced pluripotent stem cell technology in regenerative medicine.

Feng Zhang1, Fudiman Citra, Dong-An Wang.   

Abstract

Induced pluripotent stem (iPS) cells are derived from adult somatic cells via reprogramming with ectopic expression of four transcription factors (Oct3/4, Sox2, c-Myc and Klf4; or, Oct3/4, Sox2, Nanog, and Lin28), by which the resultant cells regain pluripotency, namely, the capability exclusively possessed by some embryonic cells to differentiate into any cell lineage under proper conditions. Given the ease in cell sourcing and a waiver of ethical opponency, iPS cells excel embryonic pluripotent cells in the practice of drug discovery and regenerative medicine. With an ex vivo practice in regenerative medicine, many problems involved in conventional medicine dosing, such as immune rejection, could be potentially circumvented. In this article, we briefly summarize the fundamentals and status quo of iPS-related applications, and emphasize the prospects of iPS technology in regenerative medicine.

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Year:  2011        PMID: 21210760     DOI: 10.1089/ten.TEB.2010.0549

Source DB:  PubMed          Journal:  Tissue Eng Part B Rev        ISSN: 1937-3368            Impact factor:   6.389


  13 in total

Review 1.  Regenerative surgery: tissue engineering in general surgical practice.

Authors:  Victor W Wong; Derrick C Wan; Geoffrey C Gurtner; Michael T Longaker
Journal:  World J Surg       Date:  2012-10       Impact factor: 3.352

2.  Substrate nanotexture and hypergravity through centrifugation enhance initial osteoblastogenesis.

Authors:  Ljupcho Prodanov; Jack J W A van Loon; Joost te Riet; John A Jansen; X Frank Walboomers
Journal:  Tissue Eng Part A       Date:  2012-09-14       Impact factor: 3.845

Review 3.  Long noncoding RNAs: new players in the molecular mechanism for maintenance and differentiation of pluripotent stem cells.

Authors:  Suman Ghosal; Shaoli Das; Jayprokas Chakrabarti
Journal:  Stem Cells Dev       Date:  2013-05-14       Impact factor: 3.272

4.  Cell culture density affects the stemness gene expression of adipose tissue-derived mesenchymal stem cells.

Authors:  Dae Seong Kim; Myoung Woo Lee; Tae-Hee Lee; Ki Woong Sung; Hong Hoe Koo; Keon Hee Yoo
Journal:  Biomed Rep       Date:  2017-01-19

Review 5.  Strategies for Oral Mucosal Repair by Engineering 3D Tissues with Pluripotent Stem Cells.

Authors:  Kyle J Hewitt; Yulia Shamis; Behzad Gerami-Naini; Jonathan A Garlick
Journal:  Adv Wound Care (New Rochelle)       Date:  2014-12-01       Impact factor: 4.730

Review 6.  Use of human pluripotent stem cells to study and treat retinopathies.

Authors:  Karim Ben M'Barek; Florian Regent; Christelle Monville
Journal:  World J Stem Cells       Date:  2015-04-26       Impact factor: 5.326

7.  Induction of pluripotent stem cells from a cynomolgus monkey using a polycistronic simian immunodeficiency virus-based vector, differentiation toward functional cardiomyocytes, and generation of stably expressing reporter lines.

Authors:  Stephanie Wunderlich; Alexandra Haase; Sylvia Merkert; Jennifer Beier; Kristin Schwanke; Axel Schambach; Silke Glage; Gudrun Göhring; Eliza C Curnow; Ulrich Martin
Journal:  Cell Reprogram       Date:  2012-12       Impact factor: 1.987

8.  Epigenomics of human embryonic stem cells and induced pluripotent stem cells: insights into pluripotency and implications for disease.

Authors:  Alvaro Rada-Iglesias; Joanna Wysocka
Journal:  Genome Med       Date:  2011-06-07       Impact factor: 11.117

9.  Current stem cell treatments for spinal cord injury.

Authors:  R Vawda; J Wilcox; Mg Fehlings
Journal:  Indian J Orthop       Date:  2012-01       Impact factor: 1.251

Review 10.  Cellular treatments for spinal cord injury: the time is right for clinical trials.

Authors:  Michael G Fehlings; Reaz Vawda
Journal:  Neurotherapeutics       Date:  2011-10       Impact factor: 7.620
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