Microenergy shockwave therapies for female stress urinary incontinence.

Stress urinary incontinence (SUI) is one of the pelvic floor disorders affecting tens of million of women worldwide. In general, non-surgical options have relatively limited efficacy. The most effective treatment is mid-urethral sling surgery which carries substantial risks of perioperative and postoperative complications. Regenerative therapy with the injection of several types of stem cells and stem cell products is promising but further investigation is needed before clinical implementation can be considered. In recent years, the application of microenergy therapy as a non-invasive treatment for SUI has received increasing attention. Preclinical animal studies of these models have demonstrated that low-intensity extracorporeal shockwave therapy (Li-ESWT) and microenergy acoustic pulse (MAP) therapy are capable of regenerating urethral sphincter tissue and pelvic floor muscles leading to improved urinary continence. One pilot clinical trial with Li-ESWT also reported improved quality of life in women with SUI as well as the symptoms. The objective of this review is to summarize the potential mechanisms associated with Li-ESWT and MAP therapies of SUI: (I) activation of tissue-resident stem cells; (II) regeneration of musculature in the urethra and pelvic floor; (III) improvement in biomechanical property of pelvic floor muscles; (IV) modulation of cellular signaling pathways. Further studies of the molecular mechanisms, optimal treatment dosage and schedule, and potential long-term side effects are needed to provide this non-invasive regenerative therapy for millions of women with SUI.

Low-intensity extracorporeal shockwave therapy for diabetic men with erectile dysfunction: A systematic scoping review.

BACKGROUND: Erectile dysfunction (ED) is a very common complication in men with diabetes mellitus (DM). Low-intensity extracorporeal shockwave therapy (Li-ESWT) offers a promising nonsurgical treatment option for ED. A systematic scoping review investigating the outcomes of Li-ESWT in diabetic men with ED has not yet been performed. OBJECTIVES: To systematically review animal and clinical studies related to the use of Li-ESWT for treatment of DM-related ED. DATA SOURCES: PubMed, Embase, The Cochrane Library, Scopus, and Web of Science were searched, unrestricted by dates or study design. MATERIALS AND METHODS: We included qualitative studies, quantitative studies, primary research studies, meta-analyses, and research letters written in English. Full text reviewing was completed in all animal and human studies discussing Li-ESWT for the treatment of ED in subjects with DM. Data extracted included the journal citation, publication year, country of origin, study design, and a summary of the pertinent findings. RESULTS: Our search yielded nine clinical studies and 10 animal studies. The results of the clinical studies suggest that Li-ESWT is a safe and effective treatment in men with well-controlled DM and moderate or better ED. However, the benefit is less durable in diabetic men than nondiabetic men. The results of the animal studies suggest that Li-ESWT can significantly improve erectile function in diabetic rat models with ED. CONCLUSIONS: The examined studies present encouraging results for the use of Li-ESWT to treat diabetic men with ED. Future studies, particularly robust randomized controlled trials, are necessary to confirm these findings and provide long-term follow-up.

The Basic Physics of Waves, Soundwaves, and Shockwaves for Erectile Dysfunction.

INTRODUCTION: Over the past decade, low-intensity extracorporeal shockwave therapy (Li-ESWT) has emerged as a treatment modality for erectile dysfunction (ED). To better appreciate the differences between the various devices for the treatment of ED, it is imperative for physicians to understand the underlying physics of the different shockwave generators. AIM: In this article, we explain the physics of shockwaves by establishing a foundation regarding the basics of waves, specifically soundwaves. We also describe the different shockwave generators available and assess their potential clinical utility. METHODS: We reviewed basic principles of wave propagation, randomized controlled trials investigating Li-ESWT for ED and other medical diseases, and individual industry shockwave generator websites, in order to describe the basic physics underlying Li-ESWT. MAIN OUTCOME MEASURE: We primarily aimed to describe the physics underlying shockwave generators and to provide a framework for understanding the relevant subtypes and adjustable parameters. RESULTS: A wave is a disturbance in a medium that transports energy without permanently transporting matter. In shockwaves, a soundwave is generated with a speed faster than the local speed of sound. Shockwaves are classically generated by three different types of energy sources: electrohydraulic, electromagnetic, or piezoelectric, which all create a shockwave through the conversion of electric potential energy to mechanical energy. Importantly, radial pressure waves do not behave the same as conventional shockwaves and are more like "ordinary" sound waves in that they achieve a significantly lower peak pressure, a slower rise time, and propagate outwards without a focal point. CLINICAL IMPLICATIONS: Li-ESWT is not currently approved by the U.S. Food and Drug Administration and is considered investigational in the United States. However, it is currently available to patients under clinical trial protocols and it is important to understand the basic physics of shockwaves to understand the differences between the different shockwave devices. STRENGTH & LIMITATIONS: This is a comprehensive review of the physics underlying Li-ESWT but only tangentially explores the biological impact of shockwaves. CONCLUSION: Physicians currently using or those contemplating purchasing a Li-ESWT device should understand the basic physics underlying the device, as well as which treatment protocols were used to demonstrate clinical efficacy in treating ED. Katz JE, Clavijo RI, Rizk P, et al. The Basic Physics of Waves, Soundwaves, and Shockwaves for Erectile Dysfunction. Sex Med Rev 2020;8:100-105.