Summary. Indomethacin has differential effects on chondrogencic outcome depending on differentiation stage. Introduction. Heterotopic ossification (HO) is the abnormal formation of bone in soft tissues and is a frequent complication of hip replacement surgery. The standard treatment to prevent HO is administration of the NSAID indomethacin. HOs are described to develop via endochondral ossification. As it is currently unknown how indomethacin prevents HO, we aimed to define whether indomethacin might influence HO via impairing the chondrogenic phase of endochondral ossification. Materials. ATDC5, human bone marrow stem cells (hBMSCs) and rabbit periosteal agarose cultures were employed as progenitor cell models; SW1353, human articular chondrocytes and differentiated ATDC5 cells were used as matured chondrocyte cell models. All cells were cultured in the presence of (increasing) concentrations of indomethacin. The action of indomethacin was confirmed by decreased PGE. 2. levels in all experiments, and was determined by specific PGE. 2. ELISA. Gene- and protein expression analyses were employed to determine chondrogenic outcome. Results. A dose-dependent decrease in expression of Col2a1, Col10a1 and GAG content was observed when progenitor ATDC5 cells differentiating in the chondrogenic lineage were treated with increasing concentrations of indomethacin. These results were confirmed on primary hBMSCs and ex vivo periosteal agarose cultures. Even when hypertrophic differentiation of ATDC5 cells was provoked by BMP-2 (30ng/ml) the addition of indomethacin resulted in decreased hypertrophic marker expression. Interestingly, when adult chondrocytes (SW1353 and primary human articular chondrocytes) were treated with indomethacin, a clear increase in Col2a1 expression was observed. Similarly, when ATDC5 cells were differentiated for 10 days to obtain a chondrocyte phenotype and indomethacin was added from this time point onwards, low concentrations of indomethacin also resulted in increased Col2a1 expression. Conclusions. Indomethacin (dose-dependently) prevents chondrogenic and hypertrophic differentiation from progenitor cells. In addition we found thatindomethacin (in low concentrations) is able to increase the chondrogenic phenotype of maturated chondrocytes. Together, these data indicate that indomethacin has differentiation stage-dependent effects on chondrogenic differentiation and part of the HO-preventing action of indomethacin might be contributed to inhibition of chondrogenic differentiation

Heterotopic ossi?cation is the abnormal formation of bone in soft tissues and is a frequent complication of hip replacement surgery. Heterotopic ossi?cations are described to develop via endochondral ossification and standard treatment is administration of indomethacin. It is currently unknown how indomethacin influences heterotopic ossi?cation on a molecular level, therefore we aimed to determine whether indomethacin might influence heterotopic ossi?cation via impairing the chondrogenic phase of endochondral ossification. ATDC5, human bone marrow stem cells (hBMSCs) and rabbit periosteal agarose cultures were employed as progenitor cell models; SW1353, human articular chondrocytes and differentiated ATDC5 cells were used as matured chondrocyte cell models. All cells were cultured in the presence of (increasing) concentrations of indomethacin. The action of indomethacin was confirmed by decreased PGE2 levels in all experiments, and was determined by specific PGE2 ELISA. Gene- and protein expression analyses were employed to determine chondrogenic outcome. Progenitor cell models differentiating in the chondrogenic lineage (ATDC5, primary human bone marrow stem cells and ex vivo periosteal agarose cultures) were treated with increasing concentrations of indomethacin and a dose-dependent decrease in gene- and protein expression of chondrogenic and hypertrophic markers as well as decreased glycosaminoglycan content was observed. Even when hypertrophic differentiation was provoked the addition of indomethacin resulted in decreased hypertrophic marker expression. Interestingly, when mature chondrocytes were treated with indomethacin, a clear increase in collagen type 2 expression was observed. Similarly, when ATDC5 cells and bone marrow stem cells were pre-differentiated to obtain a chondrocyte phenotype and indomethacin was added from this time point onwards, low concentrations of indomethacin also resulted in increased chondrogenic differentiation. Indomethacin induces differential effects on in vitro endochondral ossification, depending on the chondrocyte's differentiation stage, with complete inhibition of chondrogenic differentiation as the most pronounced action. This observation may provide a rationale behind the elusive mode of action of indomethacin in the treatment of heterotopic ossifications

Summary. The negative impact of NSAIDs on fracture healing appears not to pertain to fractures in cancellous bone. Possibly this is because of a higher prevalence of MSCs in cancellous bone, making recruitment of distant cells via inflammatory signals less important. Introduction. It is well established that cox inhibitors (NSAIDs) impair fracture healing, also in humans. However, as they provide good pain relief it is unclear when to avoid these drugs. The healing process in cortical and cancellous fractures differs regarding progenitor cell sources, and inflammation might be involved in the recruitment of cells from distant sources. We therefore hypothesised that fractures in cancellous bone are less sensitive to reduced inflammation due to cox inhibitors. Methods. Indomethacin was used to study the role of an NSAID on shaft and metaphyseal fracture healing. 40 male 10 week old C57/bl6 mice were used, 20 of which received a stabilised mid-shaft femur fracture, whilst the other 20 received a screw inserted into the cancellous bone of the proximal tibia on one side, and a drill hole in the same area on the contralateral side. Half of the mice received injections of 1 mg/kg bodyweight of Indomethacin, twice daily for 14 days. The other half received saline. The effect of the treatment on the fracture healing was evaluated with mechanical testing, µCT, and histology. Results. Biomechanical testing (pull-out force for the screws) could detect no significant effect of indomethacin on the cancellous fracture healing. A reduction in force by more than 21 % could be excluded with 95 % confidence. The drill holes contained new bone, but µCT of this bone showed no effect of treatment on BMD, BV/TV, trabecular thickness, or trabecular number. Analysis of shaft healing is not yet completed. µCT of the first 12 femurs is available. A difference between the groups was obvious on visual inspection: Blind sorting, based on amount of callus, could identify all 6 indomethacin treated femurs and none of the controls as having an inferior callus response. More data will follow. Discussion/Conclusion. NSAIDs had no visible effect on metaphyseal healing, but a dramatic effect on the shaft fractures. Possibly, prostaglandin signaling is important for recruitment of progenitor cells to the shaft callus, whereas such cells are already present within the metaphyseal marrow

There is increasing evidence that non-steroidal anti-inflammatory drugs (NSAIDs) can adversely affect bone repair. We have, therefore, studied the in vitro effects of NSAIDs, which differentially inhibit cyclooxygenases (COX), the prostaglandin/thromboxane synthesising enzymes, on human osteoblasts. Indomethacin and the new nitric oxide (NO)-donating NSAIDs block the activity of both COX-1 and COX-2. Indomethacin and 5,5-dimethyl-3-(3 fluorophenyl)-4-(4 methylsulphonal) phenyl-2 (5H)-furanone (DFU) reduced osteoblast numbers in a dose-dependant manner and increased collagen synthesis and alkaline phosphatase activity. The reduction in osteoblast numbers was not caused by loss of adhesion and was reversible. Neither NSAID influenced DNA synthesis. There was no difference between the effects of indomethacin and DFU. NO-NSAIDs did not affect cell numbers. These results suggest that care should be taken when administering NSAIDs to patients with existing skeletal problems and that NO-NSAIDs may be safer

Objectives

Adipose-derived mesenchymal stem cells (ADMSCs) are a promising strategy for orthopaedic applications, particularly in bone repair. Ex vivo expansion of ADMSCs is required to obtain sufficient cell numbers. Xenogenic supplements should be avoided in order to minimise the risk of infections and immunological reactions. Human platelet lysate and human plasma may be an excellent material source for ADMSC expansion. In the present study, use of blood products after their recommended transfusion date to prepare human platelet lysate (HPL) and human plasma (Hplasma) was evaluated for in vitro culture expansion and osteogenesis of ADMSCs.