Lohrer, H., Nauck, T., Korakakis, V. & Malliaropoulos, N. Historical ESWT Paradigms Are Overcome: A Narrative Review. BioMed Research International2016, (2016).
Haupt, G. Use of Extracorporeal Shock Waves in the Treatment of Pseudarthrosis, Tendinopathy and Other Orthopedic Diseases. Urol.158, 4–11 (1997).
Rompe, J. D., Kirkpatrick, C. J., Küllmer, K., Schwitalle, M. & Krischek, O. Dose-related effects of shock waves on rabbit tendo Achillis: A sonographic and histological study. Bone Jt. Surg.80,546–552 (1998).
Schaden, W. et al. Shock wave therapy for acute and chronic soft tissue wounds: a feasibility study. Surg. Res.143, 1– 12 (2007).
Dumfarth, J. et al. Prophylactic Low-Energy Shock Wave Therapy Improves Wound Healing After Vein Harvesting for Coronary Artery Bypass Graft Surgery: A Prospective, Randomized Trial.Thorac. Surg.86, 1909–1913 (2008).
d’Agostino, M. C., Craig, K., Tibalt, E. & Respizzi, S. Shock wave as biological therapeutic tool: From mechanical stimulation to recovery and healing, through mechanotransduction. International Journal of Surgery24, 147–153 (2015). 7. Ingber, D. E. Cellular mechanotransduction: putting all the pieces together again. FASEB J.20, 811–827 (2006).
Moosavi-Nejad, S. F., Hosseini, S. H. R., Satoh, M. & Takayama, K. Shock wave induced cytoskeletal and morphological deformations in a human renal carcinoma cell line. Cancer Sci.97, 296–304 (2006).
Davidson, S. M., Takov, K. & Yellon, D. M. Exosomes and Cardiovascular Protection. Drugs Ther.31, 77–86 (2017).
Hergenreider, E. et al. Atheroprotective communication between endothelial cells and smooth muscle cells through miRNAs. Cell Biol.14, 249–256 (2012).
Wang, C.-J., Wu, R.-W. & Yang, Y.-J. Treatment of diabetic foot ulcers: A comparative study of extracorporeal shockwave therapy and hyperbaric oxygen therapy. Diabetes Res. Clin. Pract.92,187–193 (2011).
Mittermayr, R. et al. Extracorporeal Shock Wave Therapy (ESWT) Minimizes Ischemic Tissue Necrosis Irrespective of Application Time and Promotes Tissue Revascularization by Stimulating Angiogenesis. Surg.253, 1024–1032 (2011).
Kisch, T. et al. Remote effects of extracorporeal shock wave therapy on cutaneous microcirculation. Tissue Viability24, 140–145 (2015).
Kuo, Y. R., Wang, C. T., Wang, F. S., Chiang, Y. C. & Wang, C. J. Extracorporeal shock-wave therapy enhanced wound healing via increasing topical blood perfusion and tissue regeneration in a rat model of STZ-induced diabetes. Wound Repair Regen.17, 522–530 (2009).
Kisch, T. et al. Repetitive shock wave therapy improves muscular microcirculation. Surg. Res.201, 440–445 (2016).
Tepeköylü, C. et al. Recruitment of endothelial progenitor cells in chronic hind limb ischemia by extracorporeal shock wave therapy in rats. Surg. – Acta Chir. Austriaca43, 13 (2011).
Zhang, X., Yan, X., Wang, C., Tang, T. & Chai, Y. The dose-effect relationship in extracorporeal shock wave therapy: the optimal parameter for extracorporeal shock wave therapy. Surg. Res.186, 484–92 (2014).
Wang, C. J., Yang, Y. J. & Huang, C. C. The effects of shockwave on systemic concentrations of nitric oxide level, angiogenesis and osteogenesis factors in hip necrosis. Int.31, 871–877 (2011).
Mittermayr, R. et al. Extracorporeal shock wave therapy (ESWT) for wound healing: Technology, mechanisms, and clinical efficacy. Wound Repair and Regeneration20, 456–465 (2012).
Gotte, G. et al. Short-time non-enzymatic nitric oxide synthesis from L-arginine and hydrogen peroxide induced by shock waves treatment. FEBS Lett.520, 153–155 (2002).
Antonic, V., Mittermayr, R., Schaden, W. & Stojadinovic, A. Evidence Supporting Extracorporeal Shockwave Therapy for Acute and Chronic Soft Tissue Wounds. WOUNDS-A Compend. Clin. Res. Pract.23, 204–215 (2011).
Tepeköylü, C. et al. Shock wave treatment induces angiogenesis and mobilizes endogenous CD31/CD34-positive endothelial cells in a hindlimb ischemia model: Implications for angiogenesis and vasculogenesis. Thorac. Cardiovasc. Surg. (2013). doi:10.1016/j.jtcvs.2013.01.017
Aicher, A. et al. Low-energy shock wave for enhancing recruitment of endothelial progenitor cells: A new modality to increase efficacy of cell therapy in chronic hind limb ischemia. Circulation114, 2823–2830 (2006).
Fleckenstein, J., Friton, M., Himmelreich, H. & Banzer, W. Effect of a Single Administration of Focused Extracorporeal Shock Wave in the Relief of Delayed-Onset Muscle Soreness: Results of a Partially Blinded Randomized Controlled Trial. Phys. Med. Rehabil.98, 923–930 (2017).
Sukubo, N. G., Tibalt, E., Respizzi, S., Locati, M. & d’Agostino, M. C. Effect of shock waves on macrophages: A possible role in tissue regeneration and remodeling. J. Surg.24, 124–130 (2015).
Holfeld, J. et al. Shockwave therapy differentially stimulates endothelial cells: implications on the control of inflammation via toll-Like receptor 3. Inflammation37, 65–70 (2014).
Cai, Z. et al. Effects of Shock Waves on Expression of IL-6, IL-8, MCP-1, and TNF-alpha Expression by Human Periodontal Ligament Fibroblasts: An In Vitro Study. Sci. Monit.22, 914–921 (2016).
Stojadinovic, A. et al. Angiogenic response to extracorporeal shock wave treatment in murine skin isografts. Angiogenesis11, 369–380 (2008).
Holfeld, J. et al. Low-energy shock wave treatment induces angiogenesis in ischemic muscle by stimulation of toll-like receptor 3 signaling. Hear. J. Acute Cardiovasc. Care128, 61–62 (2013).
Kuo, Y. R. et al. Extracorporeal shock wave treatment modulates skin fibroblast recruitment and leukocyte infiltration for enhancing extended skin-flap survival. Wound Repair Regen.17, 80–87 (2009).
Davis, T. A. et al. Extracorporeal shock wave therapy suppresses the early proinflammatory immune response to a severe cutaneous burn injury. Int Wound J6, 11–21 (2009).
Notarnicola, A. & Moretti, B. The biological effects of extracorporeal shock wave therapy (eswt) on tendon tissue. Ligaments Tendons J.2, 33–37 (2012).
Zhai, L. et al. Effects of Focused Extracorporeal Shock Waves on Bone Marrow Mesenchymal Stem Cells in Patients with Avascular Necrosis of the Femoral Head. Ultrasound Med. Biol.42,753–762 (2016).
Yin, T.-C., Wang, C.-J., Yang, K. D., Wang, F.-S. & Sun, Y.-C. Shockwaves enhance the osteogenetic gene expression in marrow stromal cells from hips with osteonecrosis. Chang Gung Med. J.34, 367–74 (2011).
Ma, H. Z., Zeng, B. F., Li, X. L. & Chai, Y. M. Temporal and spatial expression of BMP-2 in sub-chondral bone of necrotic femoral heads in rabbits by use of extracorporeal shock waves. Acta Orthop.79, 98–105 (2008).
Ma, H. Z., Zeng, B. F. & Li, X. L. Upregulation of VEGF in subchondral bone of necrotic femoral heads in rabbits with use of extracorporeal shock waves. Tissue Int.81, 124–131 (2007).
Viganò, M. et al. Mesenchymal stem cells as therapeutic target of biophysical stimulation for the treatment of musculoskeletal disorders. Orthop. Surg. Res.11, 163 (2016).
Raabe, O. et al. Effect of extracorporeal shock wave on proliferation and differentiation of equine adipose tissue-derived mesenchymal stem cells in vitro. J. Stem Cells2, 62–73 (2013).
Chen, Y. J. et al. Recruitment of mesenchymal stem cells and expression of TGF-β1 and VEGF in the early stage of shock wave-promoted bone regeneration of segmental defect in rats.Orthop. Res.22, 526–534 (2004).
Wang, F. S., Yang, K. D., Chen, R. F., Wang, C. J. & Sheen-Chen, S. M. Extracorporeal shock wave promotes growth and differentiation of bone-marrow stromal cells towards osteoprogenitors associated with induction of TGF-beta1. Bone Joint Surg. Br.84, 457–61 (2002).
Cheng, J. H. & Wang, C. J. Biological mechanism of shockwave in bone. International Journal of Surgery24, 143–146 (2015).
Wang, F.-S. et al. Physical Shock Wave Mediates Membrane Hyperpolarization and Ras Activation for Osteogenesis in Human Bone Marrow Stromal Cells. Biophys. Res. Commun.287, 648–655 (2001).
Chen, Y. J. et al. Activation of extracellular signal-regulated kinase (ERK) and p38 kinase in shock wave-promoted bone formation of segmental defect in rats. Bone34, 466–477 (2004).
Van Der Jagt, O. P. et al. Unfocused extracorporeal shock waves induce anabolic effects in osteoporotic rats. Orthop. Res.31, 768–775 (2013).
Wang, C. J. et al. Extracorporeal shockwave therapy shows chondroprotective effects in osteoarthritic rat knee. Orthop. Trauma Surg.131, 1153–1158 (2011).
Wang, F. S. et al. Ras Induction of Superoxide Activates ERK-dependent Angiogenic Transcription Factor HIF-1α and VEGFA Expression in Shock Wave-stimulated Osteoblasts. Biol. Chem.279, 10331–10337 (2004).
Wang, C. J., Yang, K. D., Wang, F. S., Hsu, C. C. & Chen, H. H. Shock wave treatment shows dose-dependent enhancement of bone mass and bone strength after fracture of the femur. Bone34,225–230 (2004).
Chao, Y. H. et al. Effects of Shock Waves on Tenocyte Proliferation and Extracellular Matrix Metabolism. Ultrasound Med. Biol.34, 841–852 (2008).
Vetrano, M. et al. Extracorporeal shock wave therapy promotes cell proliferation and collagen synthesis of primary cultured human tenocytes. Knee Surgery, Sport. Traumatol. Arthrosc.19,2159–2168 (2011).
Leone, L. et al. Extracorporeal Shock Wave Treatment (ESWT) Improves In Vitro Functional Activities of Ruptured Human Tendon-Derived Tenocytes. PLoS One7, (2012).
BOSCH, G. et al. Effect of extracorporeal shock wave therapy on the biochemical composition and metabolic activity of tenocytes in normal tendinous structures in ponies. Equine Vet. J.39,226–231 (2007).
Zhang, D., Kearney, C. J., Cheriyan, T., Schmid, T. M. & Spector, M. Extracorporeal shockwave-induced expression of lubricin in tendons and septa. Cell Tissue Res.346, 255–262 (2011).
Waugh, C. M. et al. In vivo biological response to extracorporeal shockwave therapy in human tendinopathy. Cell. Mater.29, 268–80; discussion 280 (2015).
Orhan, Z., Ozturan, K., Guven, a & Cam, K. The effect of extracorporeal shock waves on a rat model of injury to tendo Achillis. A histological and biomechanical study. Bone Joint Surg. Br.86,613–618 (2004).
Lyon, R., Liu, X. C., Kubin, M. & Schwab, J. Does extracorporeal shock wave therapy enhance healing of osteochondritis dissecans of the rabbit knee?: A pilot study knee. Orthop. Relat. Res.471, 1159–1165 (2013).
Wang, Q. et al. Effect of low-energy shock waves in microfracture holes in the repair of articular cartilage defects in a rabbit model. Med. J. (Engl).124, 1386–1394 (2011).
Mayer-Wagner, S. et al. The effect of high-energy extracorporeal shock waves on hyaline cartilage of adult rats in vivo.
Orthop. Res.28, 1050–1056 (2010).
Zhao, Z. et al. Extracorporeal shock-wave therapy reduces progression of knee osteoarthritis in rabbits by reducing nitric oxide level and chondrocyte apoptosis. Orthop. Trauma Surg.132,1547–1553 (2012).
Ertürk, C. et al. The effect of extracorporeal shockwaves on cartilage end-plates in rabbits: A preliminary MRI and histopathological study. Acta Orthop. Traumatol. Turc.46, 449–454 (2012).
Väterlein, N., Lüssenhop, S., Hahn, M., Delling, G. & Meiss, a L. The effect of extracorporeal shock waves on joint cartilage–an in vivo study in rabbits. Orthop. Trauma Surg.120, 403–406 (2000).
Byron, C. R., Benson, B. M., Stewart, A. A. & Stewart, M. C. Effects of radial shock waves on membrane permeability and viability of chondrocytes and structure of articular cartilage in equine cartilage explants. J. Vet. Res.66, 1757–1763 (2005).
Zissler, A. et al. Extracorporeal Shock Wave Therapy Accelerates Regeneration After Acute Skeletal Muscle Injury. J. Sports Med. 1–9 (2016). doi:10.1177/0363546516668622
Wang, B. et al. Low-intensity extracorporeal shock wave therapy promotes myogenesis through PERK/ATF4 pathway. Neurourology and Urodynamics (2017). doi:10.1002/nau.23380
Rinella, L. et al. Extracorporeal shock waves modulate myofibroblast differentiation of adipose-derived stem cells. Wound Repair Regen.24, 275–286 (2016).
Wang, C.-J., Huang, H.-Y. & Pai, C.-H. Shock wave-enhanced neovascularization at the tendon-bone junction: An experiment in dogs. Foot Ankle Surg.41, 16–22 (2002).
Tettenborn, B., Mehnert, S. & Reuter, I. Peripheral Nerve Injuries in Sports . Fortschritte der Neurol. Psychiatr.84, 551– 567 (2016).
Hausner, T. & Nógrádi, A. The use of shock waves in peripheral nerve regeneration: New Perspectives? Rev. Neurobiol.109, 85–98 (2013).
Mense, S. & Hoheisel, U. Shock wave treatment improves nerve regeneration in the rat. Muscle Nerve47, 702–710 (2013).
Hausner, T. et al. Improved rate of peripheral nerve regeneration induced by extracorporeal shock wave treatment in the rat. Neurol.236, 363–370 (2012).
Li, H. et al. Low-energy Shock Wave Therapy Ameliorates Erectile Dysfunction in a Pelvic Neurovascular Injuries Rat Model. Sex. Med.13, 22–32 (2016).
Manganotti, P., Amelio, E. & Guerra, C. Shock wave over hand muscles: a neurophysiological study on peripheral conduction nerves in normal subjects. Ligaments Tendons J.2, 104–107 (2012).
Rompe, J. D., Bohl, J., Riehle, H. M., Schwitalle, M. & Krischek, O. [Evaluating the risk of sciatic nerve damage in the rabbit by administration of low and intermediate energy extracorporeal shock waves]. Z Orthop Ihre Grenzgeb136, 407–411 (1998).
Yamaya, S. et al. Low-energy extracorporeal shock wave therapy promotes vascular endothelial growth factor expression and improves locomotor recovery after spinal cord injury. Neurosurg.121, 1514–1525 (2014).
Lee, J.-H. & Kim, S.-G. Effects of extracorporeal shock wave therapy on functional recovery and neurotrophin-3 expression in the spinal cord after crushed sciatic nerve injury in rats. Ultrasound Med. Biol.41, 790–6 (2015).
S. LITVINENKO, O. B. DOBROVOLSKY, V. V. KURSHEV, L.V. VESELOVA, G. V. D. EFFECTS OF EXTRACORPOREAL SHOCKWAVE THERAPY ON THE PAIN SYNDROME IN DISEASES AND INJURIES OF THE MUSCULOSKELETAL SYSTEM IN ATHLETES. Sport. Med. Res. Pract. doi:10.17238
Maier, M., Averbeck, B., Milz, S., Refior, H. J. & Schmitz, C. Substance P and prostaglandin E2 release after shock wave application to the rabbit femur. Orthop. Relat. Res. 237–245 (2003). doi:10.1097/01.blo.0000030173.56585.8f
Takahashi, N., Wada, Y., Ohtori, S., Saisu, T. & Moriya, H. Application of shock waves to rat skin decreases calcitonin gene-related peptide immunoreactivity in dorsal root ganglion neurons.Neurosci. Basic Clin.107, 81–84 (2003).
Ramon, S., Gleitz, M., Hernandez, L. & Romero, L. D. Update on the efficacy of extracorporeal shockwave treatment for myofascial pain syndrome and fibromyalgia. International Journal of Surgery24, 201–206 (2015).
Ji, H. M., Kim, H. J. & Han, S. J. Extracorporeal shock wave therapy in myofascial pain syndrome of upper trapezius. Rehabil. Med.36, 675–680 (2012).