Meniscal injuries are common and often induce knee pain requiring surgical intervention. To develop effective strategies for meniscus regeneration, we hypothesized that a minced meniscus embedded in an atelocollagen gel, a firm gel-like material, may enhance meniscus regeneration through cell migration and proliferation in the gel. Hence, the objective of this study was to investigate cell migration and proliferation in atelocollagen gels seeded with autologous meniscus fragments in vitro and examine the therapeutic potential of this combination in an in vivo rabbit model of massive meniscus defect. A total of 34 Japanese white rabbits (divided into defect and atelocollagen groups) were used to produce the massive meniscus defect model through a medial patellar approach. Cell migration and proliferation were evaluated using immunohistochemistry. Furthermore, histological evaluation of the sections was performed, and a modified Pauli’s scoring system was used for the quantitative evaluation of the regenerated meniscus.Aims
Methods
Options for the treatment of intra-articular ligament injuries are limited, and insufficient ligament reconstruction can cause painful joint instability, loss of function, and progressive development of degenerative arthritis. This study aimed to assess the capability of a biologically enhanced matrix material for ligament reconstruction to withstand tensile forces within the joint and enhance ligament regeneration needed to regain joint function. A total of 18 New Zealand rabbits underwent bilateral anterior cruciate ligament reconstruction by autograft, FiberTape, or FiberTape-augmented autograft. Primary outcomes were biomechanical assessment (n = 17), microCT (µCT) assessment (n = 12), histological evaluation (n = 12), and quantitative polymerase chain reaction (qPCR) analysis (n = 6).Aims
Materials and Methods
To compare the effect of femoral bone tunnel configuration on tendon-bone healing in an anterior cruciate ligament (ACL) reconstruction animal model. Anterior cruciate ligament reconstruction using the plantaris tendon as graft material was performed on both knees of 24 rabbits (48 knees) to mimic ACL reconstruction by two different suspensory fixation devices for graft fixation. For the adjustable fixation device model (Socket group; group S), a 5 mm deep socket was created in the lateral femoral condyle (LFC) of the right knee. For the fixed-loop model (Tunnel group; group T), a femoral tunnel penetrating the LFC was created in the left knee. Animals were sacrificed at four and eight weeks after surgery for histological evaluation and biomechanical testing.Objectives
Methods
This animal study compares different methods
of performing an osteotomy, including using an Erbium-doped Yttrium
Aluminum Garnet laser, histologically, radiologically and biomechanically.
A total of 24 New Zealand rabbits were divided into four groups
(Group I: multihole-drilling; Group II: Gigli saw; Group III: electrical
saw blade and Group IV: laser). A proximal transverse diaphyseal
osteotomy was performed on the right tibias of the rabbits after the
application of a circular external fixator. The rabbits were killed
six weeks after the procedure, the operated tibias were resected
and radiographs taken. The specimens were tested biomechanically using three-point bending
forces, and four tibias from each group were examined histologically.
Outcome parameters were the biomechanical stability of the tibias
as assessed by the failure to load and radiographic and histological
examination of the osteotomy site. The osteotomies healed in all specimens both radiographically
and histologically. The differences in the mean radiographic (p
= 0.568) and histological (p = 0.71) scores, and in the mean failure
loads (p = 0.180) were not statistically significant between the
groups. Different methods of performing an osteotomy give similar quality
of union. The laser osteotomy, which is not widely used in orthopaedics
is an alternative to the current methods. Cite this article:
The lack of effective treatment for cartilage defects has prompted investigations using tissue engineering techniques for their regeneration and repair. The success of tissue-engineered repair of cartilage may depend on the rapid and efficient adhesion of transplanted cells to a scaffold. Our aim in this study was to repair full-thickness defects in articular cartilage in the weight-bearing area of a porcine model, and to investigate whether the CD44 monoclonal antibody biotin-avidin (CBA) binding technique could provide satisfactory tissue-engineered cartilage. Cartilage defects were created in the load-bearing region of the lateral femoral condyle of mini-type pigs. The defects were repaired with traditional tissue-engineered cartilage, tissue-engineered cartilage constructed with the biotin-avidin (BA) technique, tissue-engineered cartilage constructed with the CBA technique and with autologous cartilage. The biomechanical properties, Western blot assay, histological findings and immunohistochemical staining were explored.Objectives
Methods
We investigated whether strontium-enriched calcium
phosphate cement (Sr-CPC)-treated soft-tissue tendon graft results
in accelerated healing within the bone tunnel in reconstruction
of the anterior cruciate ligament (ACL). A total of 30 single-bundle
ACL reconstructions using tendo Achillis allograft were performed
in 15 rabbits. The graft on the tested limb was treated with Sr-CPC,
whereas that on the contralateral limb was untreated and served
as a control. At timepoints three, six, nine, 12 and 24 weeks after
surgery, three animals were killed for histological examination.
At six weeks, the graft–bone interface in the control group was
filled in with fibrovascular tissue. However, the gap in the Sr-CPC
group had already been completely filled in with new bone, and there
was evidence of the early formation of Sharpey fibres. At 24 weeks,
remodelling into a normal ACL–bone-like insertion was found in the
Sr-CPC group. Coating of Sr-CPC on soft tissue tendon allograft
leads to accelerated graft healing within the bone tunnel in a rabbit
model of ACL reconstruction using Achilles tendon allograft. Cite this article:
