BACKGROUND: Clinical results of regenerative treatments for osteoarthritis are becoming increasingly significant. However, several questions remain UNANSWERED concerning mesenchymal stem cell (MSC) adhesion and incorporation into cartilage. METHODS: To this end, peripheral blood (PB) MSCs were chondrogenically induced and/or stimulated with pulsed electromagnetic fields (PEMFs) for a brief period of time just sufficient to prime differentiation. In an organ culture study, PKH26 labelled MSCs were added at two different cell densities (0.5 x106 vs 1.0 x106). In total, 180 explants of six horses (30 per horse) were divided into five groups: no lesion (i), lesion alone (ii), lesion with naïve MSCs (iii), lesion with chondrogenically-induced MSCs (iv) and lesion with chondrogenically-induced and PEMF-stimulated MSCs (v). Half of the explants were mechanically loaded and compared with the unloaded equivalents. Within each circumstance, six explants were histologically evaluated at different time points (day 1, 5 and 14). RESULTS: COMP expression was selectively increased by chondrogenic induction (p = 0.0488). PEMF stimulation (1mT for 10 minutes) further augmented COL II expression over induced values (p = 0.0405). On the other hand, MSC markers remained constant over time after induction, indicating a largely predifferentiated state. In the unloaded group, MSCs adhered to the surface in 92.6% of the explants and penetrated into 40.7% of the lesions. On the other hand, physiological loading significantly reduced surface adherence (1.9%) and lesion filling (3.7%) in all the different conditions (p < 0.0001). Remarkably, homogenous cell distribution was characteristic for chondrogenic induced MSCs (+/- PEMFs), whereas clump formation occurred in 39% of uninduced MSC treated cartilage explants. Finally, unloaded explants seeded with a moderately low density of MSCs exhibited greater lesion filling (p = 0.0022) and surface adherence (p = 0.0161) than explants seeded with higher densities of MSCs. In all cases, the overall amount of lesion filling decreased from day 5 to 14 (p = 0.0156). CONCLUSION: The present study demonstrates that primed chondrogenic induction of MSCs at a lower cell density without loading results in significantly enhanced and homogenous MSC adhesion and incorporation into equine cartilage.
BACKGROUND: Clinical results of regenerative treatments for osteoarthritis are becoming increasingly significant. However, several questions remain UNANSWERED concerning mesenchymal stem cell (MSC) adhesion and incorporation into cartilage. METHODS: To this end, peripheral blood (PB) MSCs were chondrogenically induced and/or stimulated with pulsed electromagnetic fields (PEMFs) for a brief period of time just sufficient to prime differentiation. In an organ culture study, PKH26 labelled MSCs were added at two different cell densities (0.5 x106 vs 1.0 x106). In total, 180 explants of six horses (30 per horse) were divided into five groups: no lesion (i), lesion alone (ii), lesion with naïve MSCs (iii), lesion with chondrogenically-induced MSCs (iv) and lesion with chondrogenically-induced and PEMF-stimulated MSCs (v). Half of the explants were mechanically loaded and compared with the unloaded equivalents. Within each circumstance, six explants were histologically evaluated at different time points (day 1, 5 and 14). RESULTS: COMP expression was selectively increased by chondrogenic induction (p = 0.0488). PEMF stimulation (1mT for 10 minutes) further augmented COL II expression over induced values (p = 0.0405). On the other hand, MSC markers remained constant over time after induction, indicating a largely predifferentiated state. In the unloaded group, MSCs adhered to the surface in 92.6% of the explants and penetrated into 40.7% of the lesions. On the other hand, physiological loading significantly reduced surface adherence (1.9%) and lesion filling (3.7%) in all the different conditions (p < 0.0001). Remarkably, homogenous cell distribution was characteristic for chondrogenic induced MSCs (+/- PEMFs), whereas clump formation occurred in 39% of uninduced MSC treated cartilage explants. Finally, unloaded explants seeded with a moderately low density of MSCs exhibited greater lesion filling (p = 0.0022) and surface adherence (p = 0.0161) than explants seeded with higher densities of MSCs. In all cases, the overall amount of lesion filling decreased from day 5 to 14 (p = 0.0156). CONCLUSION: The present study demonstrates that primed chondrogenic induction of MSCs at a lower cell density without loading results in significantly enhanced and homogenous MSC adhesion and incorporation into equinecartilage.
Authors: Ana Ivanovska; Mengyu Wang; Tarlan Eslami Arshaghi; Georgina Shaw; Joel Alves; Andrew Byrne; Steven Butterworth; Russell Chandler; Laura Cuddy; James Dunne; Shane Guerin; Rob Harry; Aidan McAlindan; Ronan A Mullins; Frank Barry Journal: Front Vet Sci Date: 2022-06-10
Authors: Dinesh Parate; Alfredo Franco-Obregón; Jürg Fröhlich; Christian Beyer; Azlina A Abbas; Tunku Kamarul; James H P Hui; Zheng Yang Journal: Sci Rep Date: 2017-08-25 Impact factor: 4.379
Authors: Sarah Y Broeckx; Bert Seys; Marc Suls; Aurélie Vandenberghe; Tom Mariën; Edouard Adriaensen; Jeroen Declercq; Lore Van Hecke; Gabriele Braun; Klaus Hellmann; Jan H Spaas Journal: Stem Cells Dev Date: 2019-02-13 Impact factor: 3.272
Authors: S Y Broeckx; A M Martens; A L Bertone; L Van Brantegem; L Duchateau; L Van Hecke; M Dumoulin; M Oosterlinck; K Chiers; H Hussein; F Pille; J H Spaas Journal: Equine Vet J Date: 2019-04-13 Impact factor: 2.888
Authors: Aurélie Vandenberghe; Sarah Y Broeckx; Charlotte Beerts; Bert Seys; Marieke Zimmerman; Ineke Verweire; Marc Suls; Jan H Spaas Journal: Front Vet Sci Date: 2015-10-22
Authors: Charlotte Beerts; Marc Suls; Sarah Y Broeckx; Bert Seys; Aurélie Vandenberghe; Jeroen Declercq; Luc Duchateau; Martin A Vidal; Jan H Spaas Journal: Front Vet Sci Date: 2017-09-26