Stress urinary incontinence (SUI) is the involuntary urine leakage on effort or exertion and is the most common form of urinary incontinence. SUI is a common condition, particularly among women, affecting about 35% of women over the age of 40, and is strongly correlated with vaginal delivery, which can injure the nerve, muscle, and collagenous tissues responsible for maintaining continence. The only rehabilitation method for the maternal injuries of childbirth is pelvic floor (Kegel) exercises which strengthen the muscles of the pelvic floor and prevent leakage between voids. However, one half of patients do not achieve success with pelvic floor exercises. Therefore an adjuvant treatment to Kegel rehabilitative exercises is needed. Stem cells participate in normal repair processes and therefore have the potential to be harnessed to facilitate repair of childbirth and other injuries. Cytokine gradients produced by the injured tissues attract or home circulating stem cells to sites of injury, where they facilitate the repair process, sometimes via the same receptor-mediated mechanisms involved in homing. Recent research has demonstrated that the mechanism by which stem cells facilitate repair after injury is by secreting paracrine-acting proteins such as growth factors. Vaginal distension (VD) has been used in rodents to simulate the human maternal injuries of childbirth for investigations of the mechanisms of injury and recovery. VD results in a significant decrease in urethral resistance to leakage, taken as evidence of SUI. Stem cell homing cytokines are upregulated after VD, particularly those that attract adult mesenchymal stem cells (MSCs), and infusion of MSCs after VD results in accelerated recovery of SUI. However, the mechanisms of this improved functional repair are not known. The goal of this proposal is to investigate the mechanisms of accelerated recovery by treatment with MSCs after simulated childbirth injury, in preparation for future clinical trials. The Hypothesis to be tested in this project is that adult MSCs facilitate recovery from SUI after simulated childbirth injury via secretion of paracrine factors as are in concentrated conditioned media (CCM), and this therapeutic benefit can be achieved through the systemic delivery of MSCs due to homing of these cells to the urethra &pelvic organs via a cytokine-receptor-mediated mechanism. The hypothesis will be tested with 3 Specific Objectives (SO). The experiments of SO1 are designed to determine the most effective dosage and timing of MSC or CCM delivery to facilitate recovery from VD. The experiments of SO2 are designed to determine the receptor-mediated mechanisms of MSC homing &accelerated functional recovery from VD. The experiments of SO3 are designed to determine the paracrine factor-mediated mechanisms of accelerated functional recovery from VD. Postpartum SUI is highly predictive of SUI years later even if the postpartum SUI resolves initially. Therefore, women with postpartum SUI who are not nursing could be a population of potential primary candidates for an intervention that would both treat their current incontinence and prevent recurrence of incontinence later in life. Systemic cellular therapy could provide treatment to the site where it is needed with few side effects. In addition, noncellular methods are possible, since the paracrine factors secreted by stem cells could potentially be used to accelerate recovery in the absence of cells, as with CCM treatment. This work also has direct application to polytrauma and other multi-factorial traumatic injuries since the maternal injuries of childbirth are similarly diffuse and involve nerves, muscles, connective tissue by a variety of mechanisms including direct trauma, ischemia, stretch, and avulsion. Therefore, results from this study could be used to propose treatment for other diffuse and multi-factorial traumatic injuries, including polytrauma. As a result this work has application to veterans of OIF/OEF as well as to women and could provide a method of improving rehabilitation from these combinatorial injuries for which recovery is difficult.

Public Health Relevance

This research directly relates to the Rehabilitation R&D Priority Area of Aging. In addition, women are the fastest growing segment of the veteran population representing 14% of active duty forces and 20% of new military recruits. The maternal injuries of childbirth are diffuse and involve nerves, muscles, connective tissue by a variety of mechanisms including direct trauma, ischemia, stretch, and avulsion. As a result, this work could be used to propose adult stem cell treatment for other diffuse and multi-factorial traumatic injuries, including polytrauma and other service-related wounds. This work therefore has application to veterans of OIF/OEF, and could provide a method of improving rehabilitation from these combinatorial injuries for which recovery is difficult. Specific projects to test stem cell homing as a possible adjuvant to rehabilitative treatments after polytrauma will be developed based on the outcome of the proposed work.

Agency
National Institute of Health (NIH)
Institute
Veterans Affairs (VA)
Type
Non-HHS Research Projects (I01)
Project #
1I01RX000228-01A2
Application #
8001861
Study Section
Spinal Cord Injury & Regenerative Medicine (RRD0)
Project Start
2010-07-01
Project End
2014-06-30
Budget Start
2010-07-01
Budget End
2014-06-30
Support Year
1
Fiscal Year
2011
Total Cost
Indirect Cost
Name
Louis Stokes Cleveland VA Medical Center
Department
Type
DUNS #
093016124
City
Cleveland
State
OH
Country
United States
Zip Code
44141
Tran, Christine; Damaser, Margot S (2015) Stem cells as drug delivery methods: application of stem cell secretome for regeneration. Adv Drug Deliv Rev 82-83:1-11
Tran, Christine; Damaser, Margot S (2015) The potential role of stem cells in the treatment of urinary incontinence. Ther Adv Urol 7:22-40
Damaser, Margot S; Sievert, Karl-Dietrich (2015) Tissue engineering and regenerative medicine: bench to bedside in urology. Preface. Adv Drug Deliv Rev 82-83:v-vii
Deng, Kangli; Lin, Dan Li; Hanzlicek, Brett et al. (2015) Mesenchymal stem cells and their secretome partially restore nerve and urethral function in a dual muscle and nerve injury stress urinary incontinence model. Am J Physiol Renal Physiol 308:F92-F100
Dissaranan, Charuspong; Cruz, Michelle A; Kiedrowski, Matthew J et al. (2014) Rat mesenchymal stem cell secretome promotes elastogenesis and facilitates recovery from simulated childbirth injury. Cell Transplant 23:1395-406
Cruz, Michelle; Dissaranan, Charuspong; Cotleur, Anne et al. (2012) Pelvic organ distribution of mesenchymal stem cells injected intravenously after simulated childbirth injury in female rats. Obstet Gynecol Int 2012:612946