Implantation of Stromal Vascular Fraction Progenitors at Bone Fracture Sites: From a Rat Model to a First‐in‐Man Study
Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic‐ and vascular‐progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nud...
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| Published in | Stem cells (Dayton, Ohio) Vol. 34; no. 12; pp. 2956 - 2966 |
|---|---|
| Main Authors | , , , , , , , , , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Oxford University Press
01.12.2016
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| Subjects | |
| Online Access | Get full text |
| ISSN | 1066-5099 1549-4918 1549-4918 |
| DOI | 10.1002/stem.2478 |
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| Abstract | Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic‐ and vascular‐progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking‐plate osteosynthesis, with cell‐free grafts as control. After 8 weeks, only SVF‐treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low‐energy proximal humeral fractures in 8 patients (64‐84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture‐microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra‐operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. Stem Cells 2016;34:2956–2966
Schematic diagram of the procedure to generate and implant autologous adipose‐derived cells‐based grafts. Human adipose‐derived cells are intraoperatively isolated and loaded onto ceramic granules within fibrin hydrogels and implanted into humeral fractures. This study is performed in patients as well as in femoral fractures in rats and demonstrates both that this approach is feasible and safe and that adipose‐derived cells, without expansion or exogenous priming with morphogens, can form bone tissue and vessel structures within a fracture‐microenvironment. |
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| AbstractList | Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic‐ and vascular‐progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking‐plate osteosynthesis, with cell‐free grafts as control. After 8 weeks, only SVF‐treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low‐energy proximal humeral fractures in 8 patients (64‐84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture‐microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra‐operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. Stem Cells 2016;34:2956–2966
Schematic diagram of the procedure to generate and implant autologous adipose‐derived cells‐based grafts. Human adipose‐derived cells are intraoperatively isolated and loaded onto ceramic granules within fibrin hydrogels and implanted into humeral fractures. This study is performed in patients as well as in femoral fractures in rats and demonstrates both that this approach is feasible and safe and that adipose‐derived cells, without expansion or exogenous priming with morphogens, can form bone tissue and vessel structures within a fracture‐microenvironment. Abstract Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking-plate osteosynthesis, with cell-free grafts as control. After 8 weeks, only SVF-treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low-energy proximal humeral fractures in 8 patients (64-84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture-microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra-operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. Stem Cells 2016; 34:2956-2966 Schematic diagram of the procedure to generate and implant autologous adipose-derived cells-based grafts. Human adipose-derived cells are intraoperatively isolated and loaded onto ceramic granules within fibrin hydrogels and implanted into humeral fractures. This study is performed in patients as well as in femoral fractures in rats and demonstrates both that this approach is feasible and safe and that adipose-derived cells, without expansion or exogenous priming with morphogens, can form bone tissue and vessel structures within a fracture-microenvironment. Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking-plate osteosynthesis, with cell-free grafts as control. After 8 weeks, only SVF-treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low-energy proximal humeral fractures in 8 patients (64-84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture-microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra-operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. Stem Cells 2016;34:2956-2966 Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking-plate osteosynthesis, with cell-free grafts as control. After 8 weeks, only SVF-treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low-energy proximal humeral fractures in 8 patients (64-84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture-microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra-operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. Stem Cells 2016;34:2956-2966. Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking-plate osteosynthesis, with cell-free grafts as control. After 8 weeks, only SVF-treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low-energy proximal humeral fractures in 8 patients (64-84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture-microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra-operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. Stem Cells 2016;34:2956-2966.Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking-plate osteosynthesis, with cell-free grafts as control. After 8 weeks, only SVF-treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low-energy proximal humeral fractures in 8 patients (64-84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture-microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra-operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. Stem Cells 2016;34:2956-2966. Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone fracture healing is currently unknown. Here, we investigated whether human SVF cells directly contribute to the repair of experimental fractures in nude rats, and explored the feasibility/safety of their clinical use for augmentation of upper arm fractures in elderly individuals. Human SVF cells were loaded onto ceramic granules within fibrin gel and implanted in critical nude rat femoral fractures after locking-plate osteosynthesis, with cell-free grafts as control. After 8 weeks, only SVF-treated fractures did not fail mechanically and displayed formation of ossicles at the repair site, with vascular and bone structures formed by human cells. The same materials combined with autologous SVF cells were then used to treat low-energy proximal humeral fractures in 8 patients (64-84 years old) along with standard open reduction and internal fixation. Graft manufacturing and implantation were compatible with intraoperative settings and led to no adverse reactions, thereby verifying feasibility/safety. Biopsies of the repair tissue after up to 12 months, upon plate revision or removal, demonstrated formation of bone ossicles, structurally disconnected and morphologically distinct from osteoconducted bone, suggesting the osteogenic nature of implanted SVF cells. We demonstrate that SVF cells, without expansion or exogenous priming, can spontaneously form bone tissue and vessel structures within a fracture-microenvironment. The gained clinical insights into the biological functionality of the grafts, combined with their facile, intra-operative manufacturing modality, warrant further tests of effectiveness in larger, controlled trials. |
| Author | Studer, Patrick Schreiner, Simone Heberer, Michael Scherberich, Arnaud Rikli, Daniel Miot, Sylvie Saxer, Franziska Tchang, Laurent A.H. Todorov, Atanas Güven, Sinan Martin, Ivan Jakob, Marcel Haug, Martin Schaefer, Dirk J. |
| Author_xml | – sequence: 1 givenname: Franziska surname: Saxer fullname: Saxer, Franziska organization: University Hospital Basel, University of Basel – sequence: 2 givenname: Arnaud surname: Scherberich fullname: Scherberich, Arnaud email: ivan.martin@usb.ch organization: University Hospital Basel, University of Basel – sequence: 3 givenname: Atanas surname: Todorov fullname: Todorov, Atanas organization: University Hospital Basel, University of Basel – sequence: 4 givenname: Patrick surname: Studer fullname: Studer, Patrick organization: University Hospital Basel, University of Basel – sequence: 5 givenname: Sylvie surname: Miot fullname: Miot, Sylvie organization: University Hospital Basel, University of Basel – sequence: 6 givenname: Simone surname: Schreiner fullname: Schreiner, Simone organization: University Hospital Basel, University of Basel – sequence: 7 givenname: Sinan surname: Güven fullname: Güven, Sinan organization: University Hospital Basel, University of Basel – sequence: 8 givenname: Laurent A.H. surname: Tchang fullname: Tchang, Laurent A.H. organization: University Hospital Basel – sequence: 9 givenname: Martin surname: Haug fullname: Haug, Martin organization: University Hospital Basel – sequence: 10 givenname: Michael surname: Heberer fullname: Heberer, Michael organization: University Hospital Basel, University of Basel – sequence: 11 givenname: Dirk J. surname: Schaefer fullname: Schaefer, Dirk J. organization: University Hospital Basel – sequence: 12 givenname: Daniel surname: Rikli fullname: Rikli, Daniel organization: University Hospital Basel, University of Basel – sequence: 13 givenname: Ivan surname: Martin fullname: Martin, Ivan email: arnaud.scherberich@usb.ch organization: University Hospital Basel, University of Basel – sequence: 14 givenname: Marcel surname: Jakob fullname: Jakob, Marcel organization: University Hospital Basel, University of Basel |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/27538760$$D View this record in MEDLINE/PubMed |
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| Cites_doi | 10.1016/j.biomaterials.2008.03.012 10.1007/s00264-011-1410-8 10.1089/ten.tea.2014.0515 10.1016/j.cell.2014.12.002 10.22203/eCM.v019a13 10.1161/01.CIR.0000135466.16823.D0 10.1634/stemcells.2007-0124 10.1016/j.exphem.2004.02.004 10.1371/journal.pone.0139566 10.1016/j.injury.2011.06.015 10.4252/wjsc.v6.i5.526 10.1016/j.biomaterials.2014.05.016 10.1186/1477-7525-7-49 10.1002/jcp.22313 10.1016/j.biomaterials.2011.04.064 10.1002/jcp.1138 10.1302/0301-620X.93B4.25506 10.2106/JBJS.J.01513 10.1038/nrendo.2014.234 10.22203/eCM.v024a22 10.4067/S0716-97602012000300009 10.1097/PRS.0000000000001561 10.1002/jor.20898 10.1111/j.1582-4934.2011.01335.x 10.1002/(SICI)1097-4644(19991201)75:3<414::AID-JCB7>3.0.CO;2-C 10.1615/CritRevEukaryotGeneExpr.2015013057 10.5966/sctm.2013-0173 10.1002/jbm.820271107 10.1016/j.jcms.2004.06.002 10.1089/scd.2009.0525 10.1002/mabi.201000433 10.1007/s00586-014-3696-x 10.1097/01.blo.0000198718.91223.ca 10.1186/1752-1947-5-296 10.1126/scitranslmed.3008558 10.1089/wound.2012.0408 10.1186/1471-2474-14-337 10.1016/j.cps.2014.12.007 10.1089/scd.2014.0490 10.5435/00124635-200411000-00003 |
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| Keywords | Mesenchymal stromal cells Bone repair Adipose tissue Osteoporotic fracture Cellular therapy |
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| References | 2015; 160 2001; 189 1993; 27 2010; 19 2010; 225 2015; 11 2015; 10 2011; 11 2011; 32 1995 2012; 16 2012; 36 2011; 5 2009; 27 2015; 24 2004; 32 2004; 110 2015; 25 2013; 14 2014; 3 2015; 136 2008; 29 2011; 93 2015; 42 2004; 12 2015; 21 2011; 20 2011; 42 2014; 35 2009; 7 1999; 75 2015 2012; 24 2012; 45 2014; 6 2006; 442 2007; 25 Fraser (2022010901435988600_stem2478-bib-0019) 2014; 3 Martin (2022010901435988600_stem2478-bib-0007) 2014; 6 Myeroff (2022010901435988600_stem2478-bib-0035) 2011; 93 Meijer (2022010901435988600_stem2478-bib-0006) 2008; 29 Cox (2022010901435988600_stem2478-bib-0039) 2011; 93 Scherberich (2022010901435988600_stem2478-bib-0010) 2007; 25 Miranville (2022010901435988600_stem2478-bib-0009) 2004; 110 Bouxsein (2022010901435988600_stem2478-bib-0017) 2004; 12 Ohgushi (2022010901435988600_stem2478-bib-0022) 1993; 27 Stalder (2022010901435988600_stem2478-bib-0016) 2015; 136 Pak (2022010901435988600_stem2478-bib-0032) 2013; 14 Minteer (2022010901435988600_stem2478-bib-0038) 2015; 42 Kroeze (2022010901435988600_stem2478-bib-0024) 2015; 24 Pino (2022010901435988600_stem2478-bib-0002) 2012; 45 Neer (2022010901435988600_stem2478-bib-0015) 2006; 442 Javazon (2022010901435988600_stem2478-bib-0040) 2004; 32 Dimitriou (2022010901435988600_stem2478-bib-0034) 2011; 42 Muller (2022010901435988600_stem2478-bib-0026) 2010; 19 Sandor (2022010901435988600_stem2478-bib-0029) 2014; 3 Todeschi (2022010901435988600_stem2478-bib-0028) 2015; 24 Tchang (2022010901435988600_stem2478-bib-0021) 2015 European Medicines Agency (2022010901435988600_stem2478-bib-0018) 1995 Gronthos (2022010901435988600_stem2478-bib-0020) 2001; 189 Martin (2022010901435988600_stem2478-bib-0005) 2015; 21 Lendeckel (2022010901435988600_stem2478-bib-0030) 2004; 32 Chen (2022010901435988600_stem2478-bib-0041) 2012; 16 Rhee (2022010901435988600_stem2478-bib-0008) 2011; 20 Mehrkens (2022010901435988600_stem2478-bib-0011) 2012; 24 Vergroesen (2022010901435988600_stem2478-bib-0023) 2011; 11 Schwartz (2022010901435988600_stem2478-bib-0001) 2009; 7 Chan (2022010901435988600_stem2478-bib-0027) 2015; 160 Scherberich (2022010901435988600_stem2478-bib-0012) 2010; 225 Rodriguez (2022010901435988600_stem2478-bib-0003) 1999; 75 Glenn (2022010901435988600_stem2478-bib-0036) 2014; 6 Grayson (2022010901435988600_stem2478-bib-0004) 2015; 11 Veriter (2022010901435988600_stem2478-bib-0033) 2015; 10 Konrad (2022010901435988600_stem2478-bib-0013) 2012; 36 Pak (2022010901435988600_stem2478-bib-0031) 2011; 5 Martinez-Lorenzo (2022010901435988600_stem2478-bib-0025) 2009; 27 Guven (2022010901435988600_stem2478-bib-0014) 2011; 32 Han (2022010901435988600_stem2478-bib-0037) 2015; 25 Mirsaidi (2022010901435988600_stem2478-bib-0042) 2014; 35 |
| References_xml | – volume: 75 start-page: 414 year: 1999 end-page: 423 article-title: Abnormal osteogenesis in osteoporotic patients is reflected by altered mesenchymal stem cells dynamics publication-title: J Cell Biochem – volume: 110 start-page: 349 year: 2004 end-page: 355 article-title: Improvement of postnatal neovascularization by human adipose tissue‐derived stem cells publication-title: Circulation – volume: 3 start-page: 530 year: 2014 end-page: 540 article-title: Adipose stem cells used to reconstruct 13 cases with cranio‐maxillofacial hard‐tissue defects publication-title: Stem Cells Transl Med – volume: 36 start-page: 1051 year: 2012 end-page: 1058 article-title: Comparison of two different locking plates for two‐, three‐ and four‐part proximal humeral fractures–results of an international multicentre study publication-title: Int Orthop – volume: 6 start-page: 526 year: 2014 end-page: 539 article-title: Mesenchymal stem cells: Emerging mechanisms of immunomodulation and therapy publication-title: World J Stem Cells – volume: 25 start-page: 1823 year: 2007 end-page: 1829 article-title: Three‐dimensional perfusion culture of human adipose tissue‐derived endothelial and osteoblastic progenitors generates osteogenic constructs with intrinsic vascularization capacity publication-title: Stem Cells – volume: 24 start-page: 308 year: 2012 end-page: 319 article-title: Intraoperative engineering of osteogenic grafts combining freshly harvested, human adipose‐derived cells and physiological doses of bone morphogenetic protein‐2 publication-title: Eur Cell Mater – volume: 42 start-page: S3 year: 2011 end-page: 15 article-title: Complications following autologous bone graft harvesting from the iliac crest and using the RIA: A systematic review publication-title: Injury – volume: 225 start-page: 348 year: 2010 end-page: 353 article-title: Adipose tissue‐derived progenitors for engineering osteogenic and vasculogenic grafts publication-title: J Cell Physiol – volume: 93 start-page: 2227 year: 2011 end-page: 2236 article-title: Autogenous bone graft: Donor sites and techniques publication-title: J Bone Joint Surg Am – volume: 27 start-page: 1401 year: 1993 end-page: 1407 article-title: Osteogenic differentiation of marrow stromal stem cells in porous hydroxyapatite ceramics publication-title: J Biomed Mater Res – volume: 35 start-page: 7326 year: 2014 end-page: 7335 article-title: Therapeutic potential of adipose‐derived stromal cells in age‐related osteoporosis publication-title: Biomaterials – volume: 93 start-page: 517 year: 2011 end-page: 524 article-title: The use of the reamer‐irrigator‐aspirator to harvest mesenchymal stem cells publication-title: J Bone Joint Surg Br – volume: 442 start-page: 77 year: 2006 end-page: 82 article-title: Displaced proximal humeral fractures: Part I. Classification and evaluation. 1970 publication-title: Clin Orthop Relat Res – volume: 32 start-page: 370 year: 2004 end-page: 373 article-title: Autologous stem cells (adipose) and fibrin glue used to treat widespread traumatic calvarial defects: Case report publication-title: J Craniomaxillofac Surg – volume: 11 start-page: 140 year: 2015 end-page: 150 article-title: Stromal cells and stem cells in clinical bone regeneration publication-title: Nat Rev Endocrinol – volume: 136 start-page: 455 year: 2015 end-page: 461 article-title: Aesthetic refinement of the abdominal donor site after autologous breast reconstruction publication-title: Plast Reconstr Surg – volume: 12 start-page: 385 year: 2004 end-page: 395 article-title: Recommendations for optimal care of the fragility fracture patient to reduce the risk of future fracture publication-title: J Am Acad Orthop Surg – volume: 10 start-page: e0139566 year: 2015 article-title: Human adipose‐derived mesenchymal stem cells in cell therapy: Safety and feasibility in different “Hospital Exemption” clinical applications publication-title: PLoS One – volume: 32 start-page: 414 year: 2004 end-page: 425 article-title: Mesenchymal stem cells: Paradoxes of passaging publication-title: Exp Hematol – volume: 42 start-page: 169 year: 2015 end-page: 179 article-title: Adipose stem cells: Biology, safety, regulation, and regenerative potential publication-title: Clin Plast Surg – volume: 6 start-page: 232fs16 year: 2014 article-title: Manufacturing challenges in regenerative medicine publication-title: Sci Transl Med – volume: 5 start-page: 296 year: 2011 article-title: Regeneration of human bones in hip osteonecrosis and human cartilage in knee osteoarthritis with autologous adipose‐tissue‐derived stem cells: A case series publication-title: J Med Case Rep – volume: 16 start-page: 582 year: 2012 end-page: 593 article-title: Proliferation and differentiation potential of human adipose‐derived mesenchymal stem cells isolated from elderly patients with osteoporotic fractures publication-title: J Cell Mol Med – volume: 19 start-page: 127 year: 2010 end-page: 135 article-title: Towards an intraoperative engineering of osteogenic and vasculogenic grafts from the stromal vascular fraction of human adipose tissue publication-title: Eur Cell Mater – volume: 189 start-page: 54 year: 2001 end-page: 63 article-title: Surface protein characterization of human adipose tissue‐derived stromal cells publication-title: J Cell Physiol – volume: 14 start-page: 337 year: 2013 article-title: Safety reporting on implantation of autologous adipose tissue‐derived stem cells with platelet‐rich plasma into human articular joints publication-title: BMC Musculoskelet Disord – volume: 25 start-page: 145 year: 2015 end-page: 152 article-title: Adipose‐derived stromal vascular fraction cells: Update on clinical utility and efficacy publication-title: Crit Rev Eukaryot Gene Expr – volume: 45 start-page: 279 year: 2012 end-page: 287 article-title: In osteoporosis, differentiation of mesenchymal stem cells (MSCs) improves bone marrow adipogenesis publication-title: Biol Res – volume: 29 start-page: 3053 year: 2008 end-page: 3061 article-title: Cell based bone tissue engineering in jaw defects publication-title: Biomaterials – volume: 20 start-page: 233 year: 2011 end-page: 242 article-title: In vivo evaluation of mixtures of uncultured freshly isolated adipose‐derived stem cells and demineralized bone matrix for bone regeneration in a rat critically sized calvarial defect model publication-title: Stem Cells Dev – volume: 11 start-page: 722 year: 2011 end-page: 730 article-title: The use of poly(L‐lactide‐co‐caprolactone) as a scaffold for adipose stem cells in bone tissue engineering: Application in a spinal fusion model publication-title: Macromol Biosci – year: 1995 – volume: 160 start-page: 285 year: 2015 end-page: 298 article-title: Identification and specification of the mouse skeletal stem cell publication-title: Cell – volume: 24 start-page: 1031 year: 2015 end-page: 1042 article-title: Spinal fusion using adipose stem cells seeded on a radiolucent cage filler: A feasibility study of a single surgical procedure in goats publication-title: Eur Spine J – volume: 24 start-page: 1570 year: 2015 end-page: 1581 article-title: Transplanted umbilical cord mesenchymal stem cells modify the in vivo microenvironment enhancing angiogenesis and leading to bone regeneration publication-title: Stem Cells Dev – volume: 3 start-page: 38 year: 2014 end-page: 45 article-title: The Celution(R) system: Automated processing of adipose‐derived regenerative cells in a functionally closed system publication-title: Adv Wound Care (New Rochelle.) – volume: 27 start-page: 1499 year: 2009 end-page: 1507 article-title: Phenotype and chondrogenic differentiation of mesenchymal cells from adipose tissue of different species publication-title: J Orthop Res – volume: 21 start-page: 1 year: 2015 end-page: 13 article-title: The survey on cellular and engineered tissue therapies in Europe in 2012 publication-title: Tissue Eng Part A – volume: 32 start-page: 5801 year: 2011 end-page: 5809 article-title: Engineering of large osteogenic grafts with rapid engraftment capacity using mesenchymal and endothelial progenitors from human adipose tissue publication-title: Biomaterials – volume: 7 start-page: 49 year: 2009 article-title: Prospective evaluation of chronic pain associated with posterior autologous iliac crest bone graft harvest and its effect on postoperative outcome publication-title: Health Qual Life Outcomes – year: 2015 article-title: Pooled thrombin‐activated platelet‐rich plasma: A substitute for fetal bovine serum in the engineering of osteogenic/vasculogenic grafts publication-title: J Tissue Eng Regen Med – volume: 29 start-page: 3053 year: 2008 ident: 2022010901435988600_stem2478-bib-0006 article-title: Cell based bone tissue engineering in jaw defects publication-title: Biomaterials doi: 10.1016/j.biomaterials.2008.03.012 – volume: 36 start-page: 1051 year: 2012 ident: 2022010901435988600_stem2478-bib-0013 article-title: Comparison of two different locking plates for two-, three- and four-part proximal humeral fractures–results of an international multicentre study publication-title: Int Orthop doi: 10.1007/s00264-011-1410-8 – volume: 21 start-page: 1 year: 2015 ident: 2022010901435988600_stem2478-bib-0005 article-title: The survey on cellular and engineered tissue therapies in Europe in 2012 publication-title: Tissue Eng Part A doi: 10.1089/ten.tea.2014.0515 – volume: 160 start-page: 285 year: 2015 ident: 2022010901435988600_stem2478-bib-0027 article-title: Identification and specification of the mouse skeletal stem cell publication-title: Cell doi: 10.1016/j.cell.2014.12.002 – volume: 19 start-page: 127 year: 2010 ident: 2022010901435988600_stem2478-bib-0026 article-title: Towards an intraoperative engineering of osteogenic and vasculogenic grafts from the stromal vascular fraction of human adipose tissue publication-title: Eur Cell Mater doi: 10.22203/eCM.v019a13 – volume: 110 start-page: 349 year: 2004 ident: 2022010901435988600_stem2478-bib-0009 article-title: Improvement of postnatal neovascularization by human adipose tissue-derived stem cells publication-title: Circulation doi: 10.1161/01.CIR.0000135466.16823.D0 – volume: 25 start-page: 1823 year: 2007 ident: 2022010901435988600_stem2478-bib-0010 article-title: Three-dimensional perfusion culture of human adipose tissue-derived endothelial and osteoblastic progenitors generates osteogenic constructs with intrinsic vascularization capacity publication-title: Stem Cells doi: 10.1634/stemcells.2007-0124 – volume: 32 start-page: 414 year: 2004 ident: 2022010901435988600_stem2478-bib-0040 article-title: Mesenchymal stem cells: Paradoxes of passaging publication-title: Exp Hematol doi: 10.1016/j.exphem.2004.02.004 – volume: 10 start-page: e0139566 year: 2015 ident: 2022010901435988600_stem2478-bib-0033 article-title: Human adipose-derived mesenchymal stem cells in cell therapy: Safety and feasibility in different “Hospital Exemption” clinical applications publication-title: PLoS One doi: 10.1371/journal.pone.0139566 – volume: 42 start-page: S3 year: 2011 ident: 2022010901435988600_stem2478-bib-0034 article-title: Complications following autologous bone graft harvesting from the iliac crest and using the RIA: A systematic review publication-title: Injury doi: 10.1016/j.injury.2011.06.015 – volume: 6 start-page: 526 year: 2014 ident: 2022010901435988600_stem2478-bib-0036 article-title: Mesenchymal stem cells: Emerging mechanisms of immunomodulation and therapy publication-title: World J Stem Cells doi: 10.4252/wjsc.v6.i5.526 – year: 2015 ident: 2022010901435988600_stem2478-bib-0021 article-title: Pooled thrombin-activated platelet-rich plasma: A substitute for fetal bovine serum in the engineering of osteogenic/vasculogenic grafts publication-title: J Tissue Eng Regen Med – volume: 35 start-page: 7326 year: 2014 ident: 2022010901435988600_stem2478-bib-0042 article-title: Therapeutic potential of adipose-derived stromal cells in age-related osteoporosis publication-title: Biomaterials doi: 10.1016/j.biomaterials.2014.05.016 – volume: 7 start-page: 49 year: 2009 ident: 2022010901435988600_stem2478-bib-0001 article-title: Prospective evaluation of chronic pain associated with posterior autologous iliac crest bone graft harvest and its effect on postoperative outcome publication-title: Health Qual Life Outcomes doi: 10.1186/1477-7525-7-49 – volume: 225 start-page: 348 year: 2010 ident: 2022010901435988600_stem2478-bib-0012 article-title: Adipose tissue-derived progenitors for engineering osteogenic and vasculogenic grafts publication-title: J Cell Physiol doi: 10.1002/jcp.22313 – volume: 32 start-page: 5801 year: 2011 ident: 2022010901435988600_stem2478-bib-0014 article-title: Engineering of large osteogenic grafts with rapid engraftment capacity using mesenchymal and endothelial progenitors from human adipose tissue publication-title: Biomaterials doi: 10.1016/j.biomaterials.2011.04.064 – volume: 189 start-page: 54 year: 2001 ident: 2022010901435988600_stem2478-bib-0020 article-title: Surface protein characterization of human adipose tissue-derived stromal cells publication-title: J Cell Physiol doi: 10.1002/jcp.1138 – volume: 93 start-page: 517 year: 2011 ident: 2022010901435988600_stem2478-bib-0039 article-title: The use of the reamer-irrigator-aspirator to harvest mesenchymal stem cells publication-title: J Bone Joint Surg Br doi: 10.1302/0301-620X.93B4.25506 – year: 1995 ident: 2022010901435988600_stem2478-bib-0018 – volume: 93 start-page: 2227 year: 2011 ident: 2022010901435988600_stem2478-bib-0035 article-title: Autogenous bone graft: Donor sites and techniques publication-title: J Bone Joint Surg Am doi: 10.2106/JBJS.J.01513 – volume: 11 start-page: 140 year: 2015 ident: 2022010901435988600_stem2478-bib-0004 article-title: Stromal cells and stem cells in clinical bone regeneration publication-title: Nat Rev Endocrinol doi: 10.1038/nrendo.2014.234 – volume: 24 start-page: 308 year: 2012 ident: 2022010901435988600_stem2478-bib-0011 article-title: Intraoperative engineering of osteogenic grafts combining freshly harvested, human adipose-derived cells and physiological doses of bone morphogenetic protein-2 publication-title: Eur Cell Mater doi: 10.22203/eCM.v024a22 – volume: 45 start-page: 279 year: 2012 ident: 2022010901435988600_stem2478-bib-0002 article-title: In osteoporosis, differentiation of mesenchymal stem cells (MSCs) improves bone marrow adipogenesis publication-title: Biol Res doi: 10.4067/S0716-97602012000300009 – volume: 136 start-page: 455 year: 2015 ident: 2022010901435988600_stem2478-bib-0016 article-title: Aesthetic refinement of the abdominal donor site after autologous breast reconstruction publication-title: Plast Reconstr Surg doi: 10.1097/PRS.0000000000001561 – volume: 27 start-page: 1499 year: 2009 ident: 2022010901435988600_stem2478-bib-0025 article-title: Phenotype and chondrogenic differentiation of mesenchymal cells from adipose tissue of different species publication-title: J Orthop Res doi: 10.1002/jor.20898 – volume: 16 start-page: 582 year: 2012 ident: 2022010901435988600_stem2478-bib-0041 article-title: Proliferation and differentiation potential of human adipose-derived mesenchymal stem cells isolated from elderly patients with osteoporotic fractures publication-title: J Cell Mol Med doi: 10.1111/j.1582-4934.2011.01335.x – volume: 75 start-page: 414 year: 1999 ident: 2022010901435988600_stem2478-bib-0003 article-title: Abnormal osteogenesis in osteoporotic patients is reflected by altered mesenchymal stem cells dynamics publication-title: J Cell Biochem doi: 10.1002/(SICI)1097-4644(19991201)75:3<414::AID-JCB7>3.0.CO;2-C – volume: 25 start-page: 145 year: 2015 ident: 2022010901435988600_stem2478-bib-0037 article-title: Adipose-derived stromal vascular fraction cells: Update on clinical utility and efficacy publication-title: Crit Rev Eukaryot Gene Expr doi: 10.1615/CritRevEukaryotGeneExpr.2015013057 – volume: 3 start-page: 530 year: 2014 ident: 2022010901435988600_stem2478-bib-0029 article-title: Adipose stem cells used to reconstruct 13 cases with cranio-maxillofacial hard-tissue defects publication-title: Stem Cells Transl Med doi: 10.5966/sctm.2013-0173 – volume: 27 start-page: 1401 year: 1993 ident: 2022010901435988600_stem2478-bib-0022 article-title: Osteogenic differentiation of marrow stromal stem cells in porous hydroxyapatite ceramics publication-title: J Biomed Mater Res doi: 10.1002/jbm.820271107 – volume: 32 start-page: 370 year: 2004 ident: 2022010901435988600_stem2478-bib-0030 article-title: Autologous stem cells (adipose) and fibrin glue used to treat widespread traumatic calvarial defects: Case report publication-title: J Craniomaxillofac Surg doi: 10.1016/j.jcms.2004.06.002 – volume: 20 start-page: 233 year: 2011 ident: 2022010901435988600_stem2478-bib-0008 article-title: In vivo evaluation of mixtures of uncultured freshly isolated adipose-derived stem cells and demineralized bone matrix for bone regeneration in a rat critically sized calvarial defect model publication-title: Stem Cells Dev doi: 10.1089/scd.2009.0525 – volume: 11 start-page: 722 year: 2011 ident: 2022010901435988600_stem2478-bib-0023 article-title: The use of poly(L-lactide-co-caprolactone) as a scaffold for adipose stem cells in bone tissue engineering: Application in a spinal fusion model publication-title: Macromol Biosci doi: 10.1002/mabi.201000433 – volume: 24 start-page: 1031 year: 2015 ident: 2022010901435988600_stem2478-bib-0024 article-title: Spinal fusion using adipose stem cells seeded on a radiolucent cage filler: A feasibility study of a single surgical procedure in goats publication-title: Eur Spine J doi: 10.1007/s00586-014-3696-x – volume: 442 start-page: 77 year: 2006 ident: 2022010901435988600_stem2478-bib-0015 article-title: Displaced proximal humeral fractures: Part I. Classification and evaluation. 1970 publication-title: Clin Orthop Relat Res doi: 10.1097/01.blo.0000198718.91223.ca – volume: 5 start-page: 296 year: 2011 ident: 2022010901435988600_stem2478-bib-0031 article-title: Regeneration of human bones in hip osteonecrosis and human cartilage in knee osteoarthritis with autologous adipose-tissue-derived stem cells: A case series publication-title: J Med Case Rep doi: 10.1186/1752-1947-5-296 – volume: 6 start-page: 232fs16 year: 2014 ident: 2022010901435988600_stem2478-bib-0007 article-title: Manufacturing challenges in regenerative medicine publication-title: Sci Transl Med doi: 10.1126/scitranslmed.3008558 – volume: 3 start-page: 38 year: 2014 ident: 2022010901435988600_stem2478-bib-0019 article-title: The Celution(R) system: Automated processing of adipose-derived regenerative cells in a functionally closed system publication-title: Adv Wound Care (New Rochelle.) doi: 10.1089/wound.2012.0408 – volume: 14 start-page: 337 year: 2013 ident: 2022010901435988600_stem2478-bib-0032 article-title: Safety reporting on implantation of autologous adipose tissue-derived stem cells with platelet-rich plasma into human articular joints publication-title: BMC Musculoskelet Disord doi: 10.1186/1471-2474-14-337 – volume: 42 start-page: 169 year: 2015 ident: 2022010901435988600_stem2478-bib-0038 article-title: Adipose stem cells: Biology, safety, regulation, and regenerative potential publication-title: Clin Plast Surg doi: 10.1016/j.cps.2014.12.007 – volume: 24 start-page: 1570 year: 2015 ident: 2022010901435988600_stem2478-bib-0028 article-title: Transplanted umbilical cord mesenchymal stem cells modify the in vivo microenvironment enhancing angiogenesis and leading to bone regeneration publication-title: Stem Cells Dev doi: 10.1089/scd.2014.0490 – volume: 12 start-page: 385 year: 2004 ident: 2022010901435988600_stem2478-bib-0017 article-title: Recommendations for optimal care of the fragility fracture patient to reduce the risk of future fracture publication-title: J Am Acad Orthop Surg doi: 10.5435/00124635-200411000-00003 |
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| Snippet | Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic‐ and vascular‐progenitors, yet their relevance in bone fracture... Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone fracture... Abstract Stromal Vascular Fraction (SVF) cells freshly isolated from adipose tissue include osteogenic- and vascular-progenitors, yet their relevance in bone... |
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| SubjectTerms | Adipose tissue Aged Aged, 80 and over Animals Bone repair Cellular therapy Demography Disease Models, Animal Female Femur - diagnostic imaging Femur - pathology Follow-Up Studies Fractions Fractures Fractures, Bone - diagnostic imaging Fractures, Bone - pathology Fractures, Bone - therapy Humans Immunohistochemistry Male Mesenchymal stromal cells Middle Aged Osteogenesis Osteoporotic fracture Pain Measurement Rats Stem Cell Transplantation Stem cells Stem Cells - cytology Stromal Cells - transplantation |
| Title | Implantation of Stromal Vascular Fraction Progenitors at Bone Fracture Sites: From a Rat Model to a First‐in‐Man Study |
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