Martin Sidler

Finding NeMO—Nerve-sparing Mid-urethral Obstruction: A Pathophysiologically Accurate Model of Rodent Partial Bladder Outlet Obstruction

OBJECTIVE To develop and evaluate a novel technique modeling partial bladder outlet obstruction (pBOO) using a nerve-sparing mid-urethral obstruction (NeMO) approach. MATERIALS AND METHODS Female unoperated rats were compared to rats after NeMO, NeMO sham, proximal urethral (PU) obstruction, or PU sham. Residual volume, bladder capacity, voiding volume, and bladder mass were recorded; the contractile characteristics of isolated bladder strips were also analyzed. Additionally, we quantitated nerve fibers at the bladder neck as well as the extracellular matrix in the bladder wall. RESULTS NeMO yields a more predictable degree of obstruction vs PU, causes no animal mortality, and is easy to release. NeMO also results in a more moderate increase in bladder mass commensurate with human disease vs the exaggerated response to PU, and does not lead to the excessive bladder dilation observed after PU while showing increased residual urine and fibrosis over time, thus closely modeling human pBOO pathophysiology. Importantly, PU shams significantly incite both an undesirable mass increase as well as bladder dysfunction, correlating with a denervation injury making them unsuitable as controls when modeling a non-neurogenic pBOO. The bladder physiology and structure of NeMO-sham animals were indistinguishable from those of unoperated controls. The low complication rate and low variability of NeMO also can be applied to mice, opening the pBOO field to the full spectrum of transgenic manipulation. CONCLUSION NeMO is a pathophysiologically accurate modeling approach, with low variability and mortality, and newly paves the way for realistic and robust interpretation of omics and sequencing analytical methodologies. We therefore suggest NeMO as a new standard model when investigating pBOO.

Uropathogenic E. coli (UPEC) Infection Induces Proliferation through Enhancer of Zeste Homologue 2 (EZH2).

Host-pathogen interactions can induce epigenetic changes in the host directly, as well as indirectly through secreted factors. Previously, uropathogenic Escherichia coli (UPEC) was shown to increase DNA methyltransferase activity and expression, which was associated with methylation-dependent alterations in the urothelial expression of CDKN2A. Here, we showed that paracrine factors from infected cells alter expression of another epigenetic writer, EZH2, coordinate with proliferation. Urothelial cells were inoculated with UPEC, UPEC derivatives, or vehicle (mock infection) at low moi, washed, then maintained in media with Gentamycin. Urothelial conditioned media (CM) and extracellular vesicles (EV) were isolated after the inoculations and used to treat naïve urothelial cells. EZH2 increased with UPEC infection, inoculation-induced CM, and inoculation-induced EV vs. parallel stimulation derived from mock-inoculated urothelial cells. We found that infection also increased proliferation at one day post-infection, which was blocked by the EZH2 inhibitor UNC1999. Inhibition of demethylation at H3K27me3 had the opposite effect and augmented proliferation. CONCLUSION: Uropathogen-induced paracrine factors act epigenetically by altering expression of EZH2, which plays a key role in early host cell proliferative responses to infection.

Nerve-sparing Mid-urethral Obstruction (NeMO) in Female Small Rodents

Partial bladder outlet obstruction (pBOO) has a high prevalence, causes significant patient burden, and immense health care costs. The most common animal model to investigate bladder remodeling in pBOO are female rodents undergoing partial obstruction at the proximal urethra. Variability in the degree of obstruction and animal mortality are major concerns with proximal obstruction. Furthermore, dissecting around the proximal urethra and bladder neck jeopardizes bladder innervation. We developed a nerve-sparing mid-urethral obstruction (NeMO) model for pBOO avoiding the disadvantages of the traditional model. We approached the urethra just inferior to the pubic symphysis, which obviated the need for laparotomy as well as for dissection in this area; also, the striated urethral sphincter remained untouched. We performed NeMO in female Sprague-Dawley rats (12 obstructions, 6 sham animals) as well as in female C57/bl6 mice (20 obstructions, 18 sham animals). After two weeks, we evaluated bladder function, bladder mass, and body mass. We had no mortalities among obstructed- or sham-operated female rats; as described for the traditional proximal pBOO-method, we tied the suture around the proximal urethra and a temporarily placed 0.9 mm metal rod. NeMO induced an 85% increase in bladder mass after two weeks, average residual urine volume was 0.4 mL in partially obstructed rats while only 0.03 mL in sham animals. In mice, we tested 3 sizes of cannulas that we placed along the urethra when tying the suture. We found that using a 27-gauge cannula resulted in over 50% animal mortality; placing the 25-gauge cannula did not yield the desired response in increasing bladder mass; utilizing a 26-gauge cannula yielded favorable results with minimal animal mortality (1/8) yet a significant 2-fold increase in bladder mass.

MP81-07 REGENERATION AFTER PARTIAL CYSTECTOMY IS ASSOCIATED WITH PARTICULAR BDNF DOSEAGES AND ISOFORMS

the therapeutic outcomes were examined by conscious cystometry, histological analyses, and gene expression analyses. Next, we compared the efficacy of M-MSCs at a low dosage (1 x 10 cells) with adult bone-marrow (BM)-derived MSCs. RESULTS: Rats in the KC group exhibited irregular voiding frequencies and decreased micturition interval (MI) compared with the sham group rats. A transplantation of M-MSCs (0.25, 0.5, and 1 x 10 cells; KC þ M-MSC group) significantly increased the MI as a dose dependent manner. Bladder capacity and micturition volume of rats in the KC group decreased significantly compared with those in the sham group. However, these parameters were reversed after transplantation of M-MSCs with every cell dosage. The bladders in the KC group exhibited markedly increased infiltration of Toluidine blue stained mast cells and a higher number of TUNEL stained apoptotic cells, compared to the sham group. The administration of M-MSCs significantly reversed the infiltration of mast cell and apoptosis detected in the KC bladders. Furthermore, M-MSC therapy helped to prevent the bladder tissue fibrosis. The gene expression analyses indicated that several genes related to tissue fibrosis, including TGF-b1 and TGF-b2, were markedly upregulated in the KC bladder. However their expression was significantly suppressed by the administration of M-MSCs. Importantly, MMSCs ameliorated the bladder function of KC rats at a low dose (1 x 10) of cells for which BM-derived MSCs did not substantially improve aberrant bladder function. CONCLUSIONS: This study demonstrates for the first time the therapeutic efficacy of hESC-derived M-MSCs on KC in rats. The injection of M-MSCs restores bladder function with superior efficacy compared to BM-derived MSCs by protecting against the abnormal alteration in mast cell infiltration, apoptosis and fibrotic damage.

Intraoperative blood transfusion in pediatric patients undergoing renal transplant-Effect of renal graft size

In pediatric RT, donor allograft size often exceeds the expected recipient norms, especially in younger recipients. An “oversize” graft might not only present a technical‐ and space‐related challenge, but may possibly lead to increased demands in perioperative volume requirements due to the disparity between donor and recipient in renal blood flow. We evaluated transfusion practices at a single tertiary institution with special consideration of kidney graft size, hypothesizing that oversize graft kidneys might lead to a quantifiable increased need of blood transfusion in smaller recipients. Retrospective analysis of all patients who underwent pediatric RT from January 2004 to June 2014 at a tertiary pediatric centre was performed. Variables analyzed included patient age, weight, pre‐ and postoperative Hb concentration, graft size, EBL, amount of intraoperative blood transfusion, and preoperative use of erythropoietin. Based on graft size in relation to patients age, a SMR and an OvR were identified. A subcohort of age‐matched pairs was used to allow for comparison between groups. We calculated the expected procedure‐ and transfusion‐induced changes in Hb and compared these changes to the observed difference in pre‐ vs postoperative Hb to assess the influence of graft size on transfusion requirements. RT was performed in 188 pediatric recipients during the study period. In the matched cohort, percentage of transfused patients during transplantation in the OvR group was more than double compared with SMR (89% vs 39%, P < .001); similarly, the median number of transfused PRBC units in OvR was 1, while the median of SMR did not receive transfusion (P < .001). The difference between expected (calculated) and observed change in Hb was significantly higher in OvR with a median of 1.9 g/dL compared with SMR with a median of 1.0 g/dL (P = .026). Correspondingly, the calculated median volume taken up by a regular size kidney was significantly higher with 213 mL compared with 313 mL (P = .031) taken up by an oversize graft kidney. Median estimated intraoperative blood loss was significantly higher in OvR than in SMR (6.9 mL/kg, vs 5.3 mL/kg, respectively; P = .04). Median postoperative Hb was similar among groups (10.4 g/dL vs 10.6 g/dL for SMR vs OvR, respectively). Transplantation of an oversized kidney in pediatric RT recipients is associated with a quantifiable higher need for blood transfusion. This may be caused by a higher intraoperative EBL and/or greater blood volume sequestered by the larger renal allograft and requires further evaluation.