Rotator cuff (RC) tears are common musculoskeletal injuries which often require surgical intervention. Noninvasive pulsed electromagnetic field (PEMF) devices have been approved for treatment of long-bone fracture nonunions and as an adjunct to lumbar and cervical spine fusion surgery. This study aimed to assess the effect of continuous PEMF on postoperative RC healing in a rat RC repair model. A total of 30 Wistar rats underwent acute bilateral supraspinatus tear and repair. A miniaturized electromagnetic device (MED) was implanted at the right shoulder and generated focused PEMF therapy. The animals’ left shoulders served as controls. Biomechanical, histological, and bone properties were assessed at three and six weeks.Aims
Methods
Drilling through bone is a complex action that requires precise motor skills of an orthopedic surgeon. In order to minimize plunging and soft tissue damage, the surgeon must halt drill progression precisely following penetration of the far cortex. The purpose of this study was to create a low-cost and easy-to-use drilling simulator to train orthopedic residents in reducing the drill plunging depth. This prospective observational study was performed in the division of orthopedic surgery of a single tertiary medical center. The participants included 13 residents and 7 orthopedic specialists. The simulator consisted of a synthetic femur bone model and ordinary modeling clay, and the training unit consisted of a disposable plastic tube (∼US$14), clamps (∼US$58) and a power drill + drill bit (standard hospital equipment). Plunging depths were measured by the simulator and compared between orthopedic specialists, the 6 “senior residents” (3+ years) and the 7 “junior residents” during a training session. Measurements were taken again 2 weeks following the training session. Initially, the plunging depths of the junior residents were significantly greater compared to those of the orthopedic specialists (7.00 mm vs 5.28 mm, respectively, p < 0.038). There was no similarly significant difference between the senior residents and the orthopedic experts ([6.33 mm vs. 5.28 mm, respectively; p = 0.18). The senior residents achieved plunging depths of 5.17 mm at the end of the training session and 4.7 mm 2 weeks later compared to 7.14 mm at the end of the training session and 6 mm 2 weeks later for the junior residents. This study demonstrated the capability of a low-cost drilling simulator as a training model for reducing the plunging depth during the drilling of bone and soft tissue among junior and senior residents.
Pulsed electromagnetic fields (PEMFs) have been considered a potential treatment modality for fracture healing. As bone fracture healing and osseointegration share the same biological events, the application of PEMF stimulation to facilitate the osseointegration process of orthopedic implants has been suggested. However, the mechanism of their action remains unclear. Mammalian target of rapamycin (mTOR) signaling may affect osteoblast proliferation and differentiation. This study aimed to assess the osteogenic differentiation of mesenchymal stem cells (MSCs) under PEMF stimulation and the potential involvement of mTOR signaling pathway in this process. PEMFs were generated by a novel miniaturized electromagnetic device (MED). Potential changes in the expression of mTOR pathway components, including receptors, ligands and nuclear target genes, and their correlation with osteogenic markers and transcription factors were analyzed. PEMF exposure increased cell proliferation, adhesion and osteogenic commitment of MSCs. Osteogenic-related genes were over-expressed following PEMF treatment. Our results confirm that PEMFs contribute to activation of the mTOR pathway via upregulation of the proteins AKT, MAPP kinase, and RRAGA, suggesting that activation of the mTOR pathway is required for PEMF-stimulated osteogenic differentiation. In summary, the findings of the present study revealed that MED-generated PEMFs stimulate osteogenic differentiation and the maturation of the adipose tissue-derived MSCs via activation of the mTOR pathways. Even though further research is required to determine an optimal stimulation timing and flux density both in-vitro and in-vivo, this study results may serve a source for an adjuvant therapy to improve orthopedic implant stability, longevity and enhance fracture healing.
The effect of corticosteroids on tendon properties is poorly understood, and current data are insufficient and conflicting. The objective of this study was to evaluate the effects of corticosteroids injection on intact and injured rotator cuff (RC) through biomechanical and radiographic analyses in a rat model. 70 rats were assigned to seven groups:1)control - saline injection;2) no tear + single methylprednisolone acetate (MTA) injection; 3) no tear + triple MTA injection; 4) tear + single saline injection; 5) tear + single MTA injection; 6) tear+ triple saline injections; 7) tear+ triple MTA injections. Triple injections were repeated once a week. Following unilateral supraspinatus (SSP) injuries, MTA was injected subacromialy. Rats were sacrificed 1 week after last injection. Shoulders were harvested, grossly inspected, SSP was evaluated biomechanically. Bone density at the tendon insertion site on the greater tuberosity (GT) were assessed with micro-computed tomography (CT).Background
Methods