The novel, highly-sensitive and non-destructive method for the quantification of the osteogenic potential of bone marrow mesenchymal stem cells (BM-MSCs), by the evaluation of its hydroxyapatite (HA), in vitro is 99mTc-HDP-Labelling. 99mTc-HDP (tracer) binds rapidly to HA and this uptake can be visualized and quantified. This study was performed to evaluate if this method is suitable to perform a real-time assessment during an ongoing cell culture and if the radioactive tracer may influence the cells and their ability to differentiate.

BM-MSCs (n=3) were cultivated in 35mm-dishes. Groups 1 and 3 received DMEM-LG based osteogenic media while Groups 2 und 4 were non-osteogenic controls.

Groups 1 and 2 (multi-labelling) were incubated with 5 MBq 99mTc-HDP for 30min on day 7 (d7) and the bound activity was measured using an activimeter. Subsequently the cell-culture was continued and again labelled with 99mTc-HDP on day 14 and 21 (d14, d21).

Groups 3 and 4 (single labelling), cultivation of the respective triplicates, ended on day 7, 14 and 21 (d7, d14, d21) followed by 99mTc-HDP-Labelling.

Statistical analysis using one-factor ANOVA (p<0.05).

Absolute tracer uptake increased steadily in both osteogenic groups: 1 (d7: 0.315; d14: 1.093; d21: 3.283 MBq) and 3 (d7: 0.208; d14: 0.822; d: 212.437 MBq) and was significantly higher than in the corresponding non-osteogenic control-group (Group 2 and 4) at all timepoints. (p<0.001).

No significant negative effect of the radioactive tracer could be revealed in group 1 (multi radioactive labelling on d7, d14, d21) compared to Group 3 (singe labelling).

The 99mTc-Uptake of groups 2 and 4 was not significantly different at any time.

Our data show that the repeated exposition to 99mTc-HDP has no negative influence on the osteogenic differentiation potential of BM-MSCs. Therefore, the method is capable of determining the amount of HA during an ongoing cell culture.

Dynamic compressive loading of cartilage can support extracellular matrix (ECM) synthesis whereas abnormal loading such as disuse, static loading or altered joint biomechanics can disrupt the ECM, suppress the biosynthetic activity of chondrocytes and lead to osteoarthritis. Interactions with the pericellular matrix are believed to play a critical role in the response of chondrocytes to mechanical signals. Loading of intact cartilage explants can stimulate proteoglycan synthesis immediately while the response of chondrocytes in tissue engineering constructs dependent on the day of culture. In order to effectively utilize mechanical signals in the clinic as a non-drug-based intervention to improve cartilage regeneration after surgical treatment, it is essential to understand how ECM accumulation influences the loading response. This study explored how construct maturity affects regulation of ECM synthesis of chondrocytes exposed to dynamic loading and unraveled the molecular correlates of this response.

Human chondrocytes were expanded to passage 2, seeded into collagen scaffolds and cultured for 3, 21, or 35 days before exposure to a single loading episode. Dynamic compression was applied at 25% strain, 1 Hz, in 9 × 10 minute-intervals over 3h. Gene expression and protein alterations were characterized by qPCR and Western blotting. Proteoglycan and collagen synthesis were determined by radiolabel-incorporation over 24 hours.

Maturation of constructs during culture significantly elevated ECM deposition according to histology and GAG/DNA content and chondrocytes redifferentiated as evident from raising COL2A1 and ACAN expression. Loading of d3 constructs significantly reduced proteoglycan synthesis and ACAN expression compared to controls while the identical loading episode stimulated GAG production significantly (1.45-fold, p=0.016) in day 35 constructs. Only in mature constructs, pERK1/2 and its immediate response gene FOS were stimulated by loading. Also, SOX9 protein increased after loading only in d21 and d35 but not in d3 constructs. Interestingly, levels of phosphorylated Smad 1/5/9 protein declined during construct maturation, but no evidence was obtained for load-induced changes in pSmad 1/5/9 although BMP2 and BMP6 expression were stimulated by loading. Selected MAPK-, calcium-, Wnt- and Notch-responsive genes raised significantly independent of construct maturity albeit with a generally weaker amplitude in d3 constructs.

In conclusion, construct maturity determined whether cells showed an anabolic or catabolic response to the same loading episode and this was apparently determined by a differential SOX9 and pERK signaling response on a background of high versus low total pSmad1/5/9 protein levels. Next step is to use signaling inhibitors to investigate a causal relationship between Smad levels and a beneficial loading response in order to design cartilage replacement tissue for an optimal mechanical response for in vivo applications.

Objective

In order to effectively utilize mechanical signals in the clinic as a non-drug-based intervention to improve cartilage defect regeneration after surgical treatment, it is essential to identify crucial components of the cellular response that are typical to the anabolic process. The mechanisms behind the effect of mechanical stimulation are, however, not fully understood and the signaling pathways involved in the anabolic response of chondrocytes to mechano-transduction are not well described. Therefore, a genome-wide identification of mechano-regulated genes and candidate pathways in human chondrocytes subjected to a single anabolic loading episode was performed in this study and time evolution and re-inducibility of the response was characterized.

Summary Statement

One of the most challenging problems in osteogenic 3D-tissue engineering is, to quantify the amount of new hydroxylapatite deposition. ¹⁸F-NaF-Labeling is a new, high-sensitive method to proof and quantify the osteogenic potential of hMSCs in an in vitro 3D-model.