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Literature DB >> 25560703

Stromal cells and stem cells in clinical bone regeneration.

Warren L Grayson¹, Bruce A Bunnell², Elizabeth Martin², Trivia Frazier², Ben P Hung¹, Jeffrey M Gimble².

Abstract

Stem-cell-mediated bone repair has been used in clinical trials for the regeneration of large craniomaxillofacial defects, to slow the process of bone degeneration in patients with osteonecrosis of the femoral head and for prophylactic treatment of distal tibial fractures. Successful regenerative outcomes in these investigations have provided a solid foundation for wider use of stromal cells in skeletal repair therapy. However, employing stromal cells to facilitate or enhance bone repair is far from being adopted into clinical practice. Scientific, technical, practical and regulatory obstacles prevent the widespread therapeutic use of stromal cells. Ironically, one of the major challenges lies in the limited understanding of the mechanisms via which transplanted cells mediate regeneration. Animal models have been used to provide insight, but these models largely fail to reproduce the nuances of human diseases and bone defects. Consequently, the development of targeted approaches to optimize cell-mediated outcomes is difficult. In this Review, we highlight the successes and challenges reported in several clinical trials that involved the use of bone-marrow-derived mesenchymal or adipose-tissue-derived stromal cells. We identify several obstacles blocking the mainstream use of stromal cells to enhance skeletal repair and highlight technological innovations or areas in which novel techniques might be particularly fruitful in continuing to advance the field of skeletal regenerative medicine.

Entities: CellLine Chemical Disease Gene Species

Mesh：

Year: 2015 PMID： 25560703 PMCID： PMC4338988 DOI： 10.1038/nrendo.2014.234

Source DB: PubMed Journal: Nat Rev Endocrinol ISSN： 1759-5029 Impact factor: 43.330

130 in total

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2. Do adipose tissue-derived mesenchymal stem cells have the same osteogenic and chondrogenic potential as bone marrow-derived cells?

Authors: Gun-Il Im; Yong-Woon Shin; Kee-Byung Lee
Journal: Osteoarthritis Cartilage Date: 2005-10 Impact factor: 6.576

Review 3. Stromal stem cells: marrow-derived osteogenic precursors.

Authors: M Owen; A J Friedenstein
Journal: Ciba Found Symp Date: 1988

4. Platelet-derived growth factor and spatiotemporal cues induce development of vascularized bone tissue by adipose-derived stem cells.

Authors: Daphne L Hutton; Erika M Moore; Jeffrey M Gimble; Warren L Grayson
Journal: Tissue Eng Part A Date: 2013-05-17 Impact factor: 3.845

5. Global proteomic signature of undifferentiated human bone marrow stromal cells: evidence for donor-to-donor proteome heterogeneity.

Authors: Samuel T Mindaye; Moonjin Ra; Jessica L Lo Surdo; Steven R Bauer; Michail A Alterman
Journal: Stem Cell Res Date: 2013-06-02 Impact factor: 2.020

6. Infiltrating bone marrow mesenchymal stem cells increase prostate cancer stem cell population and metastatic ability via secreting cytokines to suppress androgen receptor signaling.

Authors: J Luo; S Ok Lee; L Liang; C-K Huang; L Li; S Wen; C Chang
Journal: Oncogene Date: 2013-06-24 Impact factor: 9.867

7. Stem cell-based therapy for prevention of delayed fracture union: a randomized and prospective preliminary study.

Authors: Meir Liebergall; Josh Schroeder; Rami Mosheiff; Zulma Gazit; Zilberman Yoram; Linda Rasooly; Anat Daskal; Amal Khoury; Yoram Weil; Shaul Beyth
Journal: Mol Ther Date: 2013-06-04 Impact factor: 11.454

8. Stromal cells from the adipose tissue-derived stromal vascular fraction and culture expanded adipose tissue-derived stromal/stem cells: a joint statement of the International Federation for Adipose Therapeutics and Science (IFATS) and the International Society for Cellular Therapy (ISCT).

Authors: Philippe Bourin; Bruce A Bunnell; Louis Casteilla; Massimo Dominici; Adam J Katz; Keith L March; Heinz Redl; J Peter Rubin; Kotaro Yoshimura; Jeffrey M Gimble
Journal: Cytotherapy Date: 2013-04-06 Impact factor: 5.414

9. Effects of aging and hypoxia-inducible factor-1 activity on angiogenic cell mobilization and recovery of perfusion after limb ischemia.

Authors: Marta Bosch-Marce; Hiroaki Okuyama; Jacob B Wesley; Kakali Sarkar; Hideo Kimura; Ye V Liu; Huafeng Zhang; Marianne Strazza; Sergio Rey; Lindsey Savino; Yi Fu Zhou; Karin R McDonald; Youn Na; Scott Vandiver; Alireza Rabi; Yuval Shaked; Robert Kerbel; Theresa Lavallee; Gregg L Semenza
Journal: Circ Res Date: 2007-10-11 Impact factor: 17.367

10. Mesenchymal stem cells.

Authors: A I Caplan
Journal: J Orthop Res Date: 1991-09 Impact factor: 3.494

114 in total

1. A mouse model for the study of transplanted bone marrow mesenchymal stem cell survival and proliferation in lumbar spinal fusion.

Authors: Ioan A Lina; Wataru Ishida; Jason A Liauw; Sheng-Fu L Lo; Benjamin D Elder; Alexander Perdomo-Pantoja; Debebe Theodros; Timothy F Witham; Christina Holmes
Journal: Eur Spine J Date: 2018-12-03 Impact factor: 3.134

2. Tantalum coating of porous carbon scaffold supplemented with autologous bone marrow stromal stem cells for bone regeneration in vitro and in vivo.

Authors: Xiaowei Wei; Dewei Zhao; Benjie Wang; Wei Wang; Kai Kang; Hui Xie; Baoyi Liu; Xiuzhi Zhang; Jinsong Zhang; Zhenming Yang
Journal: Exp Biol Med (Maywood) Date: 2016-02-02

3. HIF-1α Promotes Glutamine-Mediated Redox Homeostasis and Glycogen-Dependent Bioenergetics to Support Postimplantation Bone Cell Survival.

Authors: Steve Stegen; Nick van Gastel; Guy Eelen; Bart Ghesquière; Flora D'Anna; Bernard Thienpont; Jermaine Goveia; Sophie Torrekens; Riet Van Looveren; Frank P Luyten; Patrick H Maxwell; Ben Wielockx; Diether Lambrechts; Sarah-Maria Fendt; Peter Carmeliet; Geert Carmeliet
Journal: Cell Metab Date: 2016-02-09 Impact factor: 27.287

Review 4. Manufacturing Cell Therapies Using Engineered Biomaterials.

Authors: Amr A Abdeen; Krishanu Saha
Journal: Trends Biotechnol Date: 2017-07-12 Impact factor: 19.536

5. Editor's Spotlight/Take 5: Adipose-derived Mesenchymal Stem Cells Are Phenotypically Superior for Regeneration in the Setting of Osteonecrosis of the Femoral Head.

Authors: Seth S Leopold
Journal: Clin Orthop Relat Res Date: 2015-07-09 Impact factor: 4.176

6. Cytokines in umbilical cord blood-derived cellular product: a mechanistic insight into bone repair.

Authors: Mukta S Sane; Neha Misra; Omid Mohammad Mousa; Steve Czop; Huiyuan Tang; Larry T Khoo; Christopher D Jones; Soumyajit Banerjee Mustafi
Journal: Regen Med Date: 2018-10-22 Impact factor: 3.806

7. Osteogenic differentiation of encapsulated rat mesenchymal stem cells inside a rotating microgravity bioreactor: in vitro and in vivo evaluation.

Authors: Aysel Koç Demir; Ayşe Eser Elçin; Yaşar Murat Elçin
Journal: Cytotechnology Date: 2018-06-25 Impact factor: 2.058

Review 8. Stem and progenitor cells: advancing bone tissue engineering.

Authors: R Tevlin; G G Walmsley; O Marecic; Michael S Hu; D C Wan; M T Longaker
Journal: Drug Deliv Transl Res Date: 2016-04 Impact factor: 4.617

Review 9. Engineering Stem and Stromal Cell Therapies for Musculoskeletal Tissue Repair.

Authors: Claudia Loebel; Jason A Burdick
Journal: Cell Stem Cell Date: 2018-02-08 Impact factor: 24.633

10. Functional organic cation transporters mediate osteogenic response to metformin in human umbilical cord mesenchymal stromal cells.

Authors: Faisal E Al Jofi; Tao Ma; Dong Guo; Monica P Schneider; Yan Shu; Hockin H K Xu; Abraham Schneider
Journal: Cytotherapy Date: 2018-03-16 Impact factor: 5.414