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Orthopaedic Proceedings
Vol. 106-B, Issue SUPP_2 | Pages 6 - 6
2 Jan 2024
Orellana F Grassi A Wahl P Nuss K Neels A Zaffagnini S Parrilli A
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A comprehensive understanding of the self-repair abilities of menisci and their overall function in the knee joint requires three-dimensional information. However, previous investigations of the meniscal blood supply have been limited to two-dimensional imaging methods, which fail to accurately capture tissue complexity. In this study, micro-CT was used to analyse the 3D microvascular structure of the meniscus, providing a detailed visualization and precise quantification of the vascular network.

A contrast agent (μAngiofil®) was injected directly into the femoral artery of cadaver legs to provide the proper contrast enhancement. First, the entire knee joint was analysed with micro-CT, then to increase the applicable resolution the lateral and medial menisci were excised and investigated with a maximum resolution of up to 4 μm. The resulting micro-CT datasets were analysed both qualitatively and quantitatively. Key parameters of the vascular network, such as vascular volume fraction, vessel radius, vessel length density, and tortuosity, were separately determined for the lateral and medial meniscus, and their four circumferential zones defined by Cooper.

In accordance with previous literature, the quantitative micro-CT data confirm a decrease in vascular volume fraction along the meniscal zones. The highest concentration of blood vessels was measured in the meniscocapsular region 0, which is characterized by vascular segments with a significantly larger average radius. Furthermore, the highest vessel length density observed in zone 0 suggests a more rapid delivery of oxygen and nutrients compared to other regions. Vascular tortuosity was detected in all circumferential regions, indicating the occurrence of vascular remodelling in all tissue areas.

In conclusion, micro-CT is a non-invasive imaging technique that allows for the visualization of the internal structure of an object in three dimensions. These advanced 3D vascular analyses have the potential to establish new surgical approaches that rely on the healing potential of specific areas of the meniscus.

Acknowledgements: The authors acknowledge R. Hlushchuk, S. Halm, and O. Khoma from the University of Bern for their help with contrast agent perfusions.


Orthopaedic Proceedings
Vol. 99-B, Issue SUPP_1 | Pages 25 - 25
1 Jan 2017
Kuenzler M Nuss K Karol A Schaer M Hottiger M Raniga S von Rechenberg B Zumstein M
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Disturbed muscular architecture, fatty infiltration and muscular atrophy remain irreversible in chronic rotator cuff tears (RCT) even after repair. Poly-[ADP-ribose]-polymerase 1 (PARP-1), a nuclear factor involved in DNA damage repair, has shown to be a key element in the up-regulation of early muscle inflammation, atrophy and fat deposition. We therefore hypothesized that the absence of PARP-1 would lead to a reduction in muscular architectural damage, early inflammation, atrophy and fatty infiltration subsequent to combined tenotomy and neurectomy in a PARP-1 knock-out mouse model.

PARP-1 knock-out (KO group) and standard wild type C57BL/6 (WT group) mice were randomly allocated into three different time points (1, 6 and 12 weeks, total n=72). In all mice the supraspinatus (SSP) and infraspinatus (ISP) tendons of the left shoulder were detached and the SSP muscle was denervated according to a recently established model. Macroscopic muscle weight analysis, retraction documentation using macroscopic suture, magnetic resonance imaging, immunohistochemistry gene expression analysis using real time qPCR (RTqPCR) and histology were used to assess the differences in muscle architecture, early inflammation, fatty infiltration and atrophy between knock out and wild type mice in the supraspinatus muscle.

The SSP did retract in both groups, however; the KO muscles and tendons retracted less than the WT muscles (2.1±21mm vs 3.4±0.41mm; p=0.02). Further assessment of muscle architecture demonstrated that the pennation angle was significantly higher in the KO groups at 6 and 12 weeks (28±5 vs 36±5 and 29±4 vs 34±3; p<0.0001). Combined Tenotomy and neurectomy resulted in a significant loss of muscle mass in both groups compared to the contralateral unoperated side (KO group 62±11% and WT group 52±11%, p=0.04) at 6 weeks. But at 12 weeks postoperatively, there was a significant increase in muscle mass to near normal levels in KO group compared to the WT group (14±6% and 42±7% lower muscle mass respectively; p<0.0001) and less fatty infiltration (12.5 ± 1.82% and 19.6 ± 1.96%, p=0.027). Immunohistochemistry revealed a significant decrease in the expression of inflammatory, apoptotic, adipogenic and muscular atrophy genes at both the 1 week and 6 weeks time points, but not at 12 weeks in the KO group compared to the WT group. This was confirmed by histology.

Our study is the first to show that knocking out PARP-1 leads to decreased loss of muscle architecture, early inflammation, fatty infiltration and atrophy after combined tenotomy and neurectomy of the rotator cuff muscle. Although the macroscopic muscles reaction to injury is similar in the first 6 weeks, its ability to regenerate is much greater in the PARP-1 group leading to a near normalization of the muscle substance and muscle weight, less retraction, and less fatty infiltration after 12 weeks.


Orthopaedic Proceedings
Vol. 96-B, Issue SUPP_11 | Pages 326 - 326
1 Jul 2014
Mumme M Pelttari K Gueven S Nuss K Von Rechenberg B Jakob M Martin I Barbero A
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Summary

Nasal Chondrocytes are safe and feasible for tissue engineering approaches in articular cartilage repair.

Introduction

As compared to articular chondrocytes (AC), nasal septum chondrocytes (NC) proliferate faster and have a higher and more reproducible capacity to generate hyaline-like cartilaginous tissues. Moreover, the use of NC would allow reducing the morbidity associated with the harvesting of cartilage biopsy from the patient. The objective of the present study was to demonstrate safety and feasibility in the use of tissue engineered cartilage graft based on autologous nasal chondrocytes for the repair of articular defect in goats.