Mesenchymal stromal cells (MSC) are multipotent, self-renewing cells that are an attractive cell source for cartilage regeneration strategies. While articular chondrocytes form stable cartilage-like tissue under chondrogenic in vitro conditions, a still unsolved problem of chondrocyte production from MSC is their endochondrol development leading to the formation of transient instead of stable articular cartilage. In order to identify relevant molecular determinants of chondrocyte redifferentiation versus MSC chondrogenesis and hypertrophy, this study assessed the differential expression of members of the transforming growth factor β (TGF-β) -superfamily, their receptors and antagonists between differentiating MSC and human articular chondrocytes (HAC).

Chondrogenesis of human MSC and redifferentiation of HAC was induced in micromass pellet culture. Gene expression of MSC (n=5) and HAC (n=5) was compared using a transcriptome analysis on Illumina platform. Functional regulation of relevant candidate molecules was assessed in independent MSC and HAC populations by qRT-PCR. Smad signalling during chondrogenic differentiation was analysed by immunohistochemistry and Western Blotting. BMP signalling in both populations was modulated by co-treatment with BMP-4/7 or an inhibitor of Smad1/5/9 signalling. Proteoglycan and DNA content, collagen type II and -X deposition, gene expression of chondrogenic and hypertrophic markers as well as alkaline phosphatase (ALP) activity were quantitatively assessed at different time points.

In HAC, TGF-β receptor 2 and 3 (TGFBR2/3) were up-regulated to significantly higher levels than in MSC. BMP4, expressed during HAC expansion, was suppressed while CHL2 and CHRD levels raised. In MSC, BMP4 and BMP7 were induced while TGFBR2 and TGFBR3 were down-regulated. Staining for pSmad1/5/9 in HAC demonstrated positive cells dispersed throughout the pellets at day 3 and 5 while lower pSmad1/5/9 immunostaining was observed in MSC. In HAC and MSC pellets pSmad staining decreased during chondrogenesis, in line with Western Blot results. Medium supplementation with BMP-4/7 did not improve cartilaginous matrix deposition by MSC but raised ALP-activity. When Smad1/5/9 phosphorylation was blocked in MSC culture by dorsomorphin treatment (day 14–42) COL2A1 and COL10A1 expression decreased significantly and collagen type II and type X deposition were reduced. ALP activity dropped to 12 % of control levels.

Inhibition of pSmad1/5/9 signalling was unattractive to shift chondrogenesis of MSC away from endochondral development since it unpaired SOX9 expression and strongly reduced cartilaginous matrix deposition along with hypertrophy. Thus no simple correlation exists between beneficial pSmad2/3 versus unwanted pSmad1/5/9 signalling during MSC chondrogenesis.

Corrosion in modular taper connections of total joint replacement has become a hot topic in the orthopaedic community and failures of modular systems have been reported. The objective of the present study was to determine in vivo titanium ion levels following cementless total hip arthroplasty (THA) using a modular neck system.

A consecutive series of 173 patients who underwent cementless modular neck THA and a ceramic on polyethylene bearing was evaluated retrospectively. According to a standardized protocol, titanium ion measurements were performed on 67 patients using high-resolution inductively coupled plasma-mass spectrometry. Ion levels were compared to a control group comprising patients with non-modular titanium implants and to individuals without implants.

Although there was a higher range, modular-neck THA (unilateral THA: 3.0 μg/L (0.8–21.0); bilateral THA: 6.0 μg/L (2.0–20.0)) did not result in significant elevated titanium ion levels compared to non-modular THA (unilateral THA: 2.7 μg/L (1.1–7.0), p = 0.821; bilateral THA: 6.2 μg/L, (2.3–8.0), p = 0.638). In the modular-neck THA group, patients with bilateral implants had significantly higher titanium ion levels than patients with an unilateral implant (p < 0.001). Compared to healthy controls (0.9 μg/L (0.1–4.5)), both modular THA (unilateral: p = 0.029; bilateral p = 0.003) and non-modular THA (unilateral: p < 0.001; bilateral: p < 0.001) showed elevated titanium ion levels.

The data suggest that the present modular stem system does not result in elevated systemic titanium ion levels in the medium term when compared to non-modular stems. However, more outliner were seen in modular-neck THA. Further longitudinal studies are needed to evaluate the use of systemic titanium ion levels as an objective diagnostic tool to identify THA failure and to monitor patients following revision surgery.

Introduction: Improved biomechanics and stem fit facilitated by gender adepted dual stems and modularity has the potential to make THA easier and thereby decrease the complication rate. Increased fretting wear at the connecting interfaces may be a drawback. 10 year survival exceeding 90% is required to endorse modular necks and dual stem gender technology.

Materials and Methods: We followed the first 190 consecutive implantations of an uncemented, straight femoral stem with dual stem technology and modular necks (European Hip System (EHS)/Profemur E, Wright Medical Technology Inc., Arlington, TN, USA) and a grit blasted titanium acetabular cup with a ceramic on polyethylene bearing in 178 patients from 1992 to 1997. Mean time of follow-up evaluation was 10 (8–13) years. Titanium serum ion levels were measured to detect fretting in the metal connection.

Results: At follow-up, 21 patients (22 hips, 11.6%) had died, and 13 (14 hips, 7.4%) were lost to follow-up. One hip underwent femoral revision for a periprosthetic fracture. Overall stem survival was 99 (98–100) % at 10 years, survival with femoral revision for aseptic loosening as an end point was 100 (99–100) % at 10 years. Three acetabular components were revised, one for infection and two for aseptic loosening of the titanium shell. There was one fracture of a high offset modular neck at the laser labeling without trauma; the design was changed subsequently. The mean Harris-Hip-Score at follow-up was 88 points. 153 hips were available for radiolographic evaluation. No case of femoral or acetabular osteolysis or loosening was found. Accelerated wear was not detected on radiographs. No dislocation was found during the study period. The results showed no increased titanium serum ion levels compared to an age matched control group.

Conclusions: The complication rate with this uncemented modular gender hip system was extremely low with a high patient (and surgeon) satisfaction. The modular neck system as well as the dual stem technology proved to be reliable. The metal ion analysis revealed no elevated serum ion levels. Modular necks and dual gender stems are a reliable and durable option in primary total hip arthroplasty.

Study Design: Experimental in vivo study on New Zealand white rabbits.

Summary of Background Data: Bone Morphogenetic Protein 2 (BMP-2) is of increasing orthopaedic interest due to its osteo-inductive potency. Currently it is used in human and animal studies for posterolateral spinal fusions. However, little data is available concerning the pathophysiologic role of BMP-2 in normal and degenerated discs.

Methods: A recently established animal model was used to create mechanically induced disc degeneration of one single segment. In 6 animals, an external disc compression device was attached for 28 days. For comparison 8 animals underwent a sham operation.

Outcome Measures: The discs were analysed by a) immunohistology to determine protein content of BMP-2 and b) real time RT-PCR to quantify RNA content of BMP-2.

Results: Sham controls showed a homogeneous distribution of BMP-2 throughout the annulus fibrosus and cluster-like accumulation within the nucleus pulposus. Mechanically degenerated discs determined a reduction of positive cells with areas lacking BMP-2. Real time RT-PCR results demonstrated a statistically significant (7.92 times) upregulation of BMP-2 as compared with shams (p=0.033).

Conclusions: Mechanically induced disc degeneration is associated with a loss of BMP-2 protein. Disc cells respond with a stimulation of BMP-2 gene expression. This data confirms the role of BMP-2 in the pathophysiology of disc remodeling. It remains unclear if this mechanism of BMP-2 stimulation contributes to the disc reorganization alone or if it may also play a role in osteo-inductive processes like osteophyte formation or endplate sclerosis.

Study Design: Experimental in vivo study on New Zealand White Rabbits.

Summary of Background Data: We have developed an in-vivo rabbit model of lumbar disc degeneration. This model provides a defined loading of one single disc. However, the molecular mechanism that leads to mechanically-induced disc degeneration remains unclear.

Objective: To investigate the process of mechanically induced disc degeneration in New Zealand White Rabbits with respect to remodeling on the gene and the level of protein expression.

Subjects: Seven animals were treated with an external compression-device applying 200N on segment L3/4. Eight animals underwent sham surgery.

Outcome Measures: After 28 days discs were harvested and cut into two pieces in a sagittal plain. One piece was used for protein analysis utilizing immunohistochemical protocols for collagen I, II and aggrecan. The other half of the disc was used for quantitative real-time RT-PCR to determine gene expression of selected matrix genes.

Results: In the compression group matrix genes were upregulated: collagen I (6.46x; p=0,018), collagen II (2.14x), biglycan (2.97x; p=0,049), decorin (4.64x; p=0,043), aggrecan (1.2x), osteonectin (2.03x), fibronectin (3.48x), fibromodulin (2.6x; p=0,037). The MMP-13 gene could only be detected in compressed discs. Gene transcripts of the metalloproteinase-inhibitor TIMP-1 were 4.5 times upregulated (p=0,007). Immunohistochemical analysis revealed a decrease of aggrecan and collagen I.

Conclusions: In our animal model mechanical loading caused degradation of the matrix proteins collagen I and aggrecan. Metalloproteinases like MMP-13 trigger this degenerative process. The elevated expression of matrix genes and TIMP-1 transcripts may characterize a mechanism of compensation.