SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3125210490> ?p ?o ?g. }

Showing items 1 to 100 of ±174 with 100 items per page.

W3125210490 abstract "Abstract Background Novel therapeutic strategies for the healing of nonunion, which has serious effects on the quality of life of patients, are needed. We evaluated the therapeutic effect of local transplantation of human stromal vascular fraction (SVF) cells on fracture healing in a rat non-healing fracture model and compared the effects between freshly isolated (F) and cryopreserved (C)-SVFs. Methods Non-healing fracture model was induced in the femur of female immunodeficient rats (F344/N Jcl rnu/rnu) with cauterizing periosteum. Immediately after the creation of non-healing fracture, rats received local transplantation of F and C-SVFs suspended in phosphate-buffered saline (PBS) or the same volume of PBS without cells using the same scaffold as a control group. During 8 weeks post-surgery, radiologic, histological, immunohistochemical, and biomechanical analyses were performed to evaluate fracture healing. The comparison of radiological results was performed with a chi-square test, and the multiple comparisons of immunohistochemical, histological, and biomechanical results among groups were made using a one-way analysis of variance. A probability value of 0.05 was considered to denote statistical significance. Results At week 8, in 60% of animals receiving F-SVF cells and in 50% of animals receiving C-SVF cells, the fracture radiologically healed with bone union whereas nonunion was observed in the control group. The healing potential was also confirmed by histological and biomechanical assessments. One of the mechanisms underlying healing involving intrinsic angiogenesis/osteogenesis was enhanced in F- and C-SVF groups compared with that in the control group. Human cell-derived vasculogenesis/osteogenesis, which was also confirmed in an in vitro differentiation assay, was also enhanced in the F- and C-SVF groups compared with that in the control groups and could be another mechanism for healing. Conclusions SVF cells can enhance bone healing and cryopreserved cells have almost equal potential as fresh cells. SVF cells can be used for improving nonunion bone fracture healing as an alternative to other mesenchymal stem cells and the effect of SVF cells can be maintained under cryopreservation." @default.
W3125210490 created "2021-02-01" @default.
W3125210490 creator A5007785998 @default.
W3125210490 creator A5009787961 @default.
W3125210490 creator A5017543455 @default.
W3125210490 creator A5019321843 @default.
W3125210490 creator A5022399570 @default.
W3125210490 creator A5023016674 @default.
W3125210490 creator A5025057379 @default.
W3125210490 creator A5030625832 @default.
W3125210490 creator A5039679596 @default.
W3125210490 creator A5047078434 @default.
W3125210490 creator A5049117613 @default.
W3125210490 creator A5054288403 @default.
W3125210490 creator A5065368485 @default.
W3125210490 creator A5068873977 @default.
W3125210490 creator A5071471987 @default.
W3125210490 creator A5080712404 @default.
W3125210490 creator A5081186084 @default.
W3125210490 creator A5090757852 @default.
W3125210490 date "2021-02-04" @default.
W3125210490 modified "2023-10-18" @default.
W3125210490 title "Cryopreserved human adipose-derived stromal vascular fraction maintains fracture healing potential via angiogenesis and osteogenesis in an immunodeficient rat model" @default.
W3125210490 cites W1531899892 @default.
W3125210490 cites W1967495045 @default.
W3125210490 cites W1979242330 @default.
W3125210490 cites W1983601471 @default.
W3125210490 cites W1984098071 @default.
W3125210490 cites W1989546076 @default.
W3125210490 cites W1989852722 @default.
W3125210490 cites W1996361385 @default.
W3125210490 cites W2002036251 @default.
W3125210490 cites W2002417213 @default.
W3125210490 cites W2009639932 @default.
W3125210490 cites W2010318289 @default.
W3125210490 cites W2010359869 @default.
W3125210490 cites W2017392729 @default.
W3125210490 cites W2021634519 @default.
W3125210490 cites W2022311887 @default.
W3125210490 cites W2022848314 @default.
W3125210490 cites W2024941123 @default.
W3125210490 cites W2028228531 @default.
W3125210490 cites W2032740145 @default.
W3125210490 cites W2032940634 @default.
W3125210490 cites W2038467210 @default.
W3125210490 cites W2043585992 @default.
W3125210490 cites W2046156745 @default.
W3125210490 cites W2048109221 @default.
W3125210490 cites W2048115103 @default.
W3125210490 cites W2049481811 @default.
W3125210490 cites W2051051060 @default.
W3125210490 cites W2051598972 @default.
W3125210490 cites W2054134729 @default.
W3125210490 cites W2061072494 @default.
W3125210490 cites W2072939681 @default.
W3125210490 cites W2077271986 @default.
W3125210490 cites W2083156208 @default.
W3125210490 cites W2096026776 @default.
W3125210490 cites W2107277218 @default.
W3125210490 cites W2107863336 @default.
W3125210490 cites W2109293470 @default.
W3125210490 cites W2124857894 @default.
W3125210490 cites W2138007542 @default.
W3125210490 cites W2140652705 @default.
W3125210490 cites W2151986192 @default.
W3125210490 cites W2172299613 @default.
W3125210490 cites W2173002160 @default.
W3125210490 cites W2173497140 @default.
W3125210490 cites W2267939095 @default.
W3125210490 cites W2269365829 @default.
W3125210490 cites W2414617942 @default.
W3125210490 cites W2509662931 @default.
W3125210490 cites W2592865826 @default.
W3125210490 cites W2739388690 @default.
W3125210490 cites W2754598372 @default.
W3125210490 cites W2776256560 @default.
W3125210490 cites W2801336995 @default.
W3125210490 cites W2804350613 @default.
W3125210490 cites W2885527831 @default.
W3125210490 cites W2892235998 @default.
W3125210490 cites W2898179278 @default.
W3125210490 cites W2899227186 @default.
W3125210490 cites W3014602131 @default.
W3125210490 doi "https://doi.org/10.1186/s13287-021-02182-3" @default.
W3125210490 hasPubMedCentralId "https://www.ncbi.nlm.nih.gov/pmc/articles/7863470" @default.
W3125210490 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/33541427" @default.
W3125210490 hasPublicationYear "2021" @default.
W3125210490 type Work @default.
W3125210490 sameAs 3125210490 @default.
W3125210490 citedByCount "12" @default.
W3125210490 countsByYear W31252104902022 @default.
W3125210490 countsByYear W31252104902023 @default.
W3125210490 crossrefType "journal-article" @default.
W3125210490 hasAuthorship W3125210490A5007785998 @default.
W3125210490 hasAuthorship W3125210490A5009787961 @default.
W3125210490 hasAuthorship W3125210490A5017543455 @default.
W3125210490 hasAuthorship W3125210490A5019321843 @default.
W3125210490 hasAuthorship W3125210490A5022399570 @default.
W3125210490 hasAuthorship W3125210490A5023016674 @default.
W3125210490 hasAuthorship W3125210490A5025057379 @default.