Aims

In the context of tendon degenerative disorders, the need for innovative conservative treatments that can improve the intrinsic healing potential of tendon tissue is progressively increasing. In this study, the role of pulsed electromagnetic fields (PEMFs) in improving the tendon healing process was evaluated in a rat model of collagenase-induced Achilles tendinopathy.

Among the innovative therapeutic techniques in orthopedics, a considerable interest arose around Mesenchymal Stem Cells (MSCs) - based therapies for one-step clinical applications. In order to achieve a better cell targeting at the injury site, these applications would need a specific cell delivery system. Hence, in this study a protocol for an efficient cell delivery based on the rapid cell adhesion on the surface of lyophilized fibroin-coated alginate microcarriers (L-FAMs) was optimized by the Design of Experiment (DoE) method in accordance with the minimum requirements for one-step clinical application. Specific parameters (seeding time, intermittent or not dynamic culture, stirring speed and volume of cell suspension) were combined in 13 different protocols, tested on human Adipose derived stem cells - ASCs (n=3). Cell adhesion rate in term of DNA quantification and metabolic activity of cells adhered on L-FAMs, and their qualitative observations by Calcein Staining were evaluated. The data showed that a suspension of 3.75 × 10⁵ cells/ml and 10 mg/ml of FAMs, 12.3 rpm of stirring speed and 85.6 minutes of seeding time are the most performing combination of parameters. The final protocol was then tested and validated on both hASCs (n=3) and human bone marrow derived stem cells - BMSCs (n=3). The results confirmed a high adhesion rate of cells, homogenously arranged on the surface of L-FAMs without cell cluster formation. Even though further optimizations are still needed, the present protocol may represent the proof of concept for the introduction of L-FAMs as carriers in one-step intraoperative applications.

Tendon-related pathologies such as tendinopathy represent a relevant clinical and socioeconomic issue. The most innovative and conservative therapeutic approaches are meant to stimulate the intrinsic healing capability of the tissue. In this study, the use of pulsed electromagnetic fields (PEMFs) was investigated in a rat model of Achilles tendinopathy as a potential therapy. Achilles tendinopathy was chemically induced in eighty-six Sprague Dawley rats by injecting collagenase Type I within the tendon fibers. Fifty-six of them were stimulated with PEMFs (8 hours/day, 1.5 ± 0.2 mT; 75 Hz), divided in different experimental groups basing on the starting-time of PEMFs exposure (after 0, 7, 15 after Collagenase injection) and its duration (7, 15 or 30 days). Thirty animals were left unstimulated (CTRL group). According to the different time points, explanted tendons were evaluated through histological and immunohistochemical analyses in term of matrix deposition, fiber re-organization, neovascularization and inflammatory reaction. The most effective PEMF stimulation was demonstrated in the 15 days of treatment. However, when PEMF were applied immediately after the collagenase injection, no significant therapeutic results were found. On the contrary, when PEMF were applied after 7 and 15 days from the collagenase injection, they promoted the deposition of extracellular matrix and tendon fiber re-organization, reducing both the inflammatory reaction and vascularization, with significant differences compared to the CTRL group (p<0.05). Therefore, these results suggest an effective activity of PEMFs stimulation that provides a satisfying restoration of the damaged tissue, although the most performing protocol of application still needs to be identified.