The ability of hMSCs to differentiate into several mesenchymal cell lineages including the osteoblast lineage plays a key role in skeletogenesis and bone regeneration. Although the importance of physical factors in the development and maintenance of bone tissue has been recognized for many years and we previously demonstrated that mechanical strain constitutes an inherent stimulus for osteogenic differentiation of undifferentiated hMSCs, there is strong evidence to suggest that obesity is an independent factor in the risk of implant failure due to aseptic loosening or fracture after TJR. While mechanical complications and overload have been widely suggested, we hypothesized that the osteogenic mechanoresponse of hMSCs may be profoundly altered in obese patients. hMSCs were isolated from bone marrow of 10 donors (BMI ranging from 18.7 to 37.6 kg/m2). The individual response of unidfferentiated hMSCs to cyclic tensile strain (CTS) was determined in a two-armed study design (strained versus unstrained (CTR)) using a 4-point bending device, where strain was restricted to a maximum of 3,000 μstrain. Phenotypic effects were characterized by analyzing cell numbers, cell viability and ALP activity; mRNA levels of marker genes related to early osteogenic differentiation (RUNX2, ALPL, SPARC, SPP1), protein synthesis (COL1A1), and cell cycle (MKI67) were determined by real-time RT-PCR. Possible contributions to anthropomorphometric variables and individual triglycerides, cholesterin, glucose, leptin, adiponectin, resistin, and estradiol levels were evaluated by linear regression analysis. We found a significant up-regulation of the osteogenic marker genes due to CTS, including RUNX2 (1.9 fold), ALPL (2.4 fold), SPP1 (2.8 fold), and SPARC (4.1 fold), which was accompanied by an increase in cell-based ALP activity from 6.1 ± 1.2 μM/min/106 in CTR to 8.5 ± 1.7 μM/min/106 in CTS (plus 39.6 ± 9.8% SEM, P<
0.05). Cell density was significantly lower following CTS (minus 20.0 ± 4.7%, P<
0.05), which was also found for cell viability (XTT minus 17.8 ± 5.6%, P<
0.05). As a consequence, the phenotypic CTS response (ALP activity w/o normalization) ranged widely between donors (−30.8% to +60.1%) and was highly significant inverse correlated to donor’s BMI (r= −0.91, P<
0.0001). Additionally, leptin and estradiol levels determined within bone marrow plasma were significantly correlated with the phenotypic mechanoresponse (r=−0.71, P=0.028, and r=0.67; P=0.039; respectively). The findings demonstrate that the osteogenic mechanosensitivity of hMSCs is highly affected by physiological factors related to donor’s BMI. Such an upstream imprinting process within bone marrow may be an important area of further research, since obesity-linked problems constitute increasing concerns in orthopaedic surgery within the western world.
The induction of differentiation is a highly programmed lineage-specific process and several studies have provided great insight into the microenvironment affecting differentiation of multipotential hMSCs. In this regard, the importance of physical factors has been recognized for many years, but only little is known about its effects on undifferentiated hMSCs. The study aimed to determine the early osteogenic differentiation response to physiologically-based mechanical tensile strain with possible contributions to donor-specific physiological conditions. MSCs of ten donors were expanded under standard culture conditions, and the individual response to cyclic tensile strain (CTS) was determined in a two-armed study design (strained versus unstrained (CTR)). CTS was applied with a maximum of 3,000 μstrain. Genotypic characteristics (RUNX2, ALPL, SPARC, SPP1; COL1A1, MKI67, etc) as well as phenotypic effects (cell numbers, cell viability and ALP activity) were compared between CTR and CTS, and possible relations to donor-specific physiological characteristics including anthropomorphometric and biochemical variables were determined. We found a significant up-regulation of the osteogenic marker genes due to CTS, which was accompanied by an increase in cell-based ALP activity (plus 39.6 ± 9.8% SEM, P<
0.05). Cell density as well as XTT were significantly lower following CTS (minus 20.0 ± 4.7% and minus 17.8 ± 5.6%, respectively, P<
0.05). As a consequence, the ALP activity w/o normalization ranged widely from minus 30.8% to plus 60.1% between individual donors and was a function of donor’s BMI (r=−0.91, P<
0.0001), weight (r=−0.73, P=0.016), and age (r=−0.65, P=0.041). The findings demonstrate that
the application of CTS provides an inherent osteogenic differentiation stimulus for undifferentiated hMSCs in vitro, and the functional response of hMSCs to CTS was found to be highly related to donor’s BMI/fat mass, thus suggesting an upstream imprinting process of the hMSCs within bone marrow