A Self-Powered Piezo-Bioelectric Device Regulates Tendon Repair-Associated Signaling Pathways through Modulation of Mechanosensitive Ion Channels.

Tendon disease constitutes an unmet clinical need and remains a critical challenge in the field of orthopaedic surgery. Innovative solutions are required to overcome the limitations of current tendon grafting approaches, and bioelectronic therapies show promise in treating musculoskeletal diseases, accelerating functional recovery through the activation of tissue regeneration-specific signaling pathways. Self-powered bioelectronic devices, particularly piezoelectric materials, represent a paradigm shift in biomedicine, negating the need for battery or external powering and complementing existing mechanotherapy to accelerate the repair processes. Here, the dynamic response of tendon cells to a piezoelectric collagen-analogue scaffold comprised of aligned nanoscale fibers made of the ferroelectric material poly(vinylidene fluoride-co-trifluoroethylene) is shown. It is demonstrated that motion-powered electromechanical stimulation of tendon tissue through piezo-bioelectric device results in ion channel modulation in vitro and regulates specific tissue regeneration signaling pathways. Finally, the potential of the piezo-bioelectronic device in modulating the progression of tendinopathy-associated processes in vivo, using a rat Achilles acute injury model is shown. This study indicates that electromechanical stimulation regulates mechanosensitive ion channel sensitivity and promotes tendon-specific over non-tenogenic tissue repair processes.

Temporal changes guided by mesenchymal stem cells on a 3D microgel platform enhance angiogenesis in vivo at a low-cell dose.

Therapeutic factors secreted by mesenchymal stem cells (MSCs) promote angiogenesis in vivo. However, delivery of MSCs in the absence of a cytoprotective environment offers limited efficacy due to low cell retention, poor graft survival, and the nonmaintenance of a physiologically relevant dose of growth factors at the injury site. The delivery of stem cells on an extracellular matrix (ECM)-based platform alters cell behavior, including migration, proliferation, and paracrine activity, which are essential for angiogenesis. We demonstrate the biophysical and biochemical effects of preconditioning human MSCs (hMSCs) for 96 h on a three-dimensional (3D) ECM-based microgel platform. By altering the macromolecular concentration surrounding cells in the microgels, the proangiogenic phenotype of hMSCs can be tuned in a controlled manner through cell-driven changes in extracellular stiffness and "outside-in" integrin signaling. The softest microgels were tested at a low cell dose (5 × 104 cells) in a preclinical hindlimb ischemia model showing accelerated formation of new blood vessels with a reduced inflammatory response impeding progression of tissue damage. Molecular analysis revealed that several key mediators of angiogenesis were up-regulated in the low-cell-dose microgel group, providing a mechanistic insight of pathways modulated in vivo. Our research adds to current knowledge in cell-encapsulation strategies by highlighting the importance of preconditioning or priming the capacity of biomaterials through cell-material interactions. Obtaining therapeutic efficacy at a low cell dose in the microgel platform is a promising clinical route that would aid faster tissue repair and reperfusion in "no-option" patients suffering from peripheral arterial diseases, such as critical limb ischemia (CLI).

Variability in Endogenous Perfusion Recovery of Immunocompromised Mouse Models of Limb Ischemia.

Immunocompromised hind limb ischemia (HLI) murine models are essential for preclinical evaluation of human cell-based therapy or biomaterial-based interventions. These models are used to generate proof of principle that the approach is effective and also regulatory preclinical data required for translation to the clinic. However, surgical variations in creation of HLI models reported in the literature introduce variability in the pathological manifestation of the model, in consequence affecting therapeutic endpoints. This study aims to compare the extent of vascular regeneration in HLI-induced immunocompromised murine models to obtain a stable and more reproducible injury model for testing. Athymic and Balb/C nude mice underwent HLI surgery with single and double ligation of femoral artery (FA). The recovery from surgery was observed over a period of 2 weeks with respect to ischemia reperfusion using laser Doppler and clinical signs of necrosis and ambulatory impairment. Double ligation of the FA results in a more severe response to ischemia in Balb/C with endogenous perfusion recovery up to 50% ± 10% compared with 75% ± 20% in athymic nude mice. Single iliac artery (IA) and FA lead to creation of mild ischemia compared with femoral artery-vein (FAV) pair ligation in Balb/C. Microcirculatory parameters indicate significantly lower capillary numbers (26 ± 3/mm(2)) and functional capillary density (203 ± 5 cm/cm(2)) in the FAV group. In this study, we demonstrate a reproducible, arterial double ligation in an immunocompromised Balb/C nude mouse model that exhibits characteristic pathological signs of ischemia with impaired endogenous recovery.