Renal Perfusion Pressure Research Articles

Abstract 03: Glomerular Hyperfiltration Promotes Chronic Kidney Disease through Interleukin 17A-Mediated Inflammation

Impaired renal autoregulation in obesity, diabetes and hypertension (HTN) causes elevated glomerular capillary pressure and glomerular hyperfiltration, initiating progressive glomerulosclerosis (GS), nephron loss and chronic kidney disease (CKD). Increased renal perfusion pressure drives renal T cell infiltration. T helper (Th) 17 cells promote vascular stiffening in HTN and renal interstitial fibrosis post AKI, but their roles in GS and CKD are poorly understood. We hypothesized that glomerular hyperfiltration promotes CKD through Th17-mediated GS and tested the hypothesis in 129S6 mice using the reduced kidney mass model (RKM) induced by uninephrectomy and partial renal artery ligation in the remaining kidney (functional renal mass reduced by ~ 5/6). BP (radiotelemetry) and GFR (FITC-sinistrin) of RKM mice were identical to sham controls at baseline (BL, n=4-6). Immediately after the RKM procedure, GFR dropped to 22% of BL, consistent with the extent of renal mass ablation. Mean BP increased by 29 mmHg first week after 5/6 ablation (144 ± 8 vs BL 112 ± 2 mmHg, p<0.05, 2-way ANOVA) and remained elevated through week 12, exposing the remnant nephrons to increased renal perfusion pressure. Serum creatinine, BUN and urinary albumin were significantly elevated after 5/6 ablation. In RKM mice, GFR gradually increased to 38% of BL at day 3, 57% at week 1 and 68% at week 2, suggesting that systemic HTN and impaired renal autoregulation may have caused substantial single-nephron hyperfiltration in the remnant kidney. GFR plateaued at ~ 70% of BL in week 3-4 then declined to 48% at week 8 when glomerular, interstitial, and microvascular fibrosis developed as evidence by Periodic Acid Schiff and Picro Sirius Red staining. Importantly, the early adaptive increase of GFR in the first 2 weeks post 5/6 ablation was accompanied by a striking increase of renal interleukin (IL)-17A+ T cells, which preceded the late infiltration of CD11b+ myeloid cells, F4/80+ monocyte/macrophages, and T regulatory cells. Anti-IL17A antibodies (eBioMM17F3, 100 μg i.p. twice weekly) attenuated the early hyperfiltration, abolished aortic/renal inflammation, and prevented GFR decline and GS at week 8 in male but not female RKM mice, likely due to the anti-hypertensive and anti-inflammatory effects of IL-17A neutralization. We conclude that glomerular hyperfiltration causes progressive nephron loss and kidney fibrosis in CKD, at least in part, through IL-17A mediated renal inflammation.

Understanding fluid dynamics and renal perfusion in acute kidney injury management.

Acute kidney injury (AKI) is associated with an increased risk of morbidity, mortality, and healthcare expenditure, posing a major challenge in clinical practice, and affecting about 50% of patients in the intensive care unit (ICU), particularly the elderly and those with pre-existing chronic comorbidities. In health, intra-renal blood flow is maintained and auto-regulated within a wide range of renal perfusion pressures (60-100 mmHg), mediated predominantly through changes in pre-glomerular vascular tone of the afferent arteriole in response to changes of the intratubular NaCl concentration, i.e. tubuloglomerular feedback. Several neurohormonal processes contribute to regulation of the renal microcirculation, including the sympathetic nervous system, vasodilators such as nitric oxide and prostaglandin E2, and vasoconstrictors such as endothelin, angiotensin II and adenosine. The most common risk factors for AKI include volume depletion, haemodynamic instability, inflammation, nephrotoxic exposure and mitochondrial dysfunction. Fluid management is an essential component of AKI prevention and management. While traditional approaches emphasize fluid resuscitation to ensure renal perfusion, recent evidence urges caution against excessive fluid administration, given AKI patients' susceptibility to volume overload. This review examines the main characteristics of AKI in ICU patients and provides guidance on fluid management, use of biomarkers, and pharmacological strategies.

The Effect of Angiotensin II Type 1 Receptor Antagonist on Age-Related Differences in Renal Vascular Responses to Angiotensin II in Male and Female Rats.

Advancing age could influence renin angiotensin system components, especially angiotensin type 1 receptor (AT1R). This study examined the effect of AT1R antagonist, losartan, on age-related differences in renal vascular responses to angiotensin II in male and female rats. Forty-eight anesthetized male and female rats (8-12 and 24-28 weeks age ranges) were subjected to catheterize. Then, the responses of mean arterial pressure (MAP), renal perfusion pressure (RPP), renal blood flow (RBF), and renal vascular resistance (RVR) to angiotensin II with or without losartan were determined and evaluated. There were not significant differences in the basal values of MAP, RPP, RBF, and RVR in males. However, it was observed significant difference in RVR in females (P < 0.05). The blockade of AT1R attenuated basal MAP and RPP in all the groups (P < 0.05). The infusion of losartan altered basal RVR and RBF values in female groups (P < 0.05). Moreover, losartan eliminated vasoconstrictor responses to angiotensin II in female groups (P < 0.05). Also, losartan induced significant vascular responses to angiotensin II in male groups (P < 0.05). Losartan could maintain RBF changes in response to angiotensin II in both 8-12- and 24-28-week females. Losartan enhanced the RBF response to angiotensin II in 8-12-week males, but not in 24-28-week males. It seems that females (not males) in various age ranges are resistance against RBF changes by acutely increased angiotensin II.

The role of preterm birth in stress-induced sodium excretion in young adults.

Early-life programming due to prematurity and very low birth weight (VLBW, <1500 g) is believed to contribute to development of hypertension, but the mechanisms remain unclear. Experimental data suggest that altered pressure natriuresis (increased renal perfusion pressure promoting sodium excretion) may be a contributing mechanism. We hypothesize that young adults born preterm will have a blunted pressure natriuresis response to mental stress compared with those born term. In this prospective cohort study of 190 individuals aged 18-23 years, 156 born preterm with VLBW and 34 controls born term with birth weight at least 2500 g, we measured urine sodium/creatinine before and after a mental stress test and continuous blood pressure before and during the stress test. Participants were stratified into groups by the trajectory at which mean arterial pressure (MAP) increased following the test. The group with the lowest MAP trajectory was the reference group. We used generalized linear models to assess poststress urine sodium/creatinine relative to the change in MAP trajectory and assessed the difference between groups by preterm birth status. Participants' mean age was 19.8 years and 57% were women. Change in urine sodium/creatinine per unit increase in MAP when comparing middle trajectory group against the reference group was greater in those born preterm [β 5.4%, 95% confidence interval (95% CI) -11.4 to 5.3] than those born term (β 38.5%, 95% CI -0.04 to 92.0), interaction term P = 0.002. We observed that, as blood pressure increased following mental stress, young adults born preterm exhibited decreased sodium excretion relative to term-born individuals.

Periods of low renal perfusion pressure are associated with acute kidney injury following paediatric cardiac surgery.

Acute kidney injury is associated with worse outcomes after cardiac surgery. The haemodynamic goals to ameliorate kidney injury are not clear. Low post-operative renal perfusion pressure has been associated with acute kidney injury in adults. Inadequate oxygen delivery may also cause kidney injury. This study evaluates pressure and oximetric haemodynamics after paediatric cardiac surgery and their association with acute kidney injury. Retrospective case-control study at a children's hospital. Patients were < 6 months of age who underwent a Society of Thoracic Surgery-European Association for Cardio-Thoracic Surgery Congenital Heart Surgery categories ≥ 3. Low renal perfusion pressure was time and depth below several tested thresholds. The primary outcome was serum creatine-defined acute kidney injury in the first 7 days. Sixty-six patients (median age 8 days) were included. Acute kidney injury occurred in 36%. The time and depth of renal perfusion pressure < 42 mmHg in the first 24 hours was greater in acute kidney injury patients (94 versus 35 mmHg*minutes of low renal perfusion pressure/hour, p = 0.008). In the multivariable model, renal perfusion pressure < 42 mmHg was associated with acute kidney injury (aOR: 2.07, 95%CI: 1.25-3.82, p = 0.009). Mean arterial pressure, central venous pressure, and measures of inadequate oxygen delivery were not associated with acute kidney injury. Periods of low renal perfusion pressure (<42 mmHg) in the first 24 post-operative hours are associated with acute kidney injury. Renal perfusion pressure is a potential modifiable target that may mitigate the impact of acute kidney injury after paediatric cardiac surgery.

Glomerular Hyperfiltration and Th17 Responses Promote Glomerulosclerosis Following Nephron Loss

Objective: Chronic kidney disease (CKD) affects 37 million Americans resulting in $87 billion healthcare cost annually. Impaired renal autoregulation in obesity, diabetes and hypertension causes elevated glomerular capillary pressure and whole-kidney hyperfiltration, leading to progressive glomerulosclerosis and CKD. In advanced CKD with less than 50% functional nephron mass, single-nephron hyperfiltration causes further nephron loss, ultimately leading to hypofiltration and end-state kidney disease. Increased renal perfusion pressure directly drives T cell infiltration to the kidney. We and others have shown that T helper (Th) 17 cells promote vascular stiffening in hypertension and renal interstitial fibrosis after ischemia-reperfusion injury, but their roles in glomerulosclerosis and CKD are poorly understood. We hypothesized that glomerular hypertension and hyperfiltration promote renal fibrosis through Th17-mediated immune responses. Methods: We investigated the causal roles of glomerular hyperfiltration and Th17 responses in a mouse CKD model induced by reduced kidney mass (RKM), which involved right kidney nephrectomy and partial renal artery ligation in the left kidney such that the functional renal mass is reduced by ~ 5/6. Male 129/S6 mice received sham or RKM surgery at 8 weeks of age, and blood pressure (BP, by radiotelemetry), glomerular filtration rate (GFR, by transcutaneous FITC-sinistrin) and serum/urine CKD markers were assessed at baseline (BL) and week 1, 2, 3, 4, 8, and 12 post-surgery. Results: BP and GFR of RKM mice were identical to sham controls at BL (n=4-6). Immediately after the RKM procedure, GFR dropped to 22% of BL, consistent with the extent of renal mass ablation. BP increased by 29 mmHg first week after 5/6 ablation (144 ± 8 vs BL 112 ± 2 mmHg, p&lt;0.05, 2-way ANOVA), exposing the remnant nephrons to increased renal perfusion pressure. Serum creatinine, blood urea nitrogen and urinary albumin were significantly elevated by week 2. BP and CKD markers remained elevated through week 12 in the 5/6 ablation mice. The GFR of ablated mice gradually increased to 38% of BL at day 3, 57% at week 1 and 68% at week 2, suggesting that systemic hypertension and impaired renal autoregulation may have caused substantial single-nephron hyperfiltration in the remnant kidney mass. GFR plateaued at ~ 70% of BL in week 3-4 then declined to 48% at week 8-12 when glomerular, interstitial, and microvascular fibrosis developed as evidence by Periodic Acid Schiff and Picro Sirius Red staining. Supporting a causal role of hemodynamic derangements in CKD progression, calcium channel blocker amlodipine, a potent vasodilator, dose dependently (5-10 mg/kg/day, n=7-9) exacerbated glomerular hyperfiltration, glomerulosclerosis and mortality despite marked BP-lowering effects. Importantly, the adaptive increase of GFR in the first 2 weeks post 5/6 ablation was accompanied by significant increase of renal Th17 cells, which not only preceded the infiltration of CD11b+ myeloid cells, F4/80+ monocyte/macrophages and T regulatory cells, but also the glomerulosclerosis and GFR decline in week 8. Conclusions: Our data suggest that glomerular hyperfiltration causes progressive nephron loss and kidney fibrosis, at least in part, through Th17-mediated renal inflammation. To further establish causality, ongoing studies will assess if Th17 blockade ameliorates glomerulosclerosis and retard CKD progression. Funding: This work was supported by NIDDK R01 DK094907, R01 DK113632, R01 DK128677 to THL, and K01 DK126972 to JW. JW is also supported by an American Heart Association Second Century Early Faculty Independence Award (23SCEFIA1148464), a University of Rochester Environmental Health Science Center pilot award (Prime sponsor: NIEHS P30ES001247), and a University of Rochester Program for Advanced Immune Bioimaging Pilot Award (Prime Sponsor: NIAID P01AI102851). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Cardiorenal Syndromes and Their Role in Water and Sodium Homeostasis

Sodium is the main osmotically active ion in the extracellular fluid and its concentration goes hand in hand with fluid volume. Under physiological conditions, homeostasis of sodium and thus amount of fluid is regulated by neural and humoral interconnection of body tissues and organs. Both heart and kidneys are crucial in maintaining volume status. Proper kidney function is necessary to excrete regulated amount of water and solutes and adequate heart function is inevitable to sustain renal perfusion pressure, oxygen supply etc. As these organs are bidirectionally interconnected, injury of one leads to dysfunction of another. This condition is known as cardiorenal syndrome. It is divided into five subtypes regarding timeframe and pathophysiology of the onset. Hemodynamic effects include congestion, decreased cardiac output, but also production of natriuretic peptides. Renal congestion and hypoperfusion leads to kidney injury and maladaptive activation of renin-angiotensin-aldosterone system and sympathetic nervous system. In cardiorenal syndromes sodium and water excretion is impaired leading to volume overload and far-reaching negative consequences, including higher morbidity and mortality of these patients. Keywords: Cardiorenal syndrome • Renocardiac syndrome • Volume overload • Sodium retention

Factors that mediate change in creatinine and acute kidney injury after the Norwood operation: insights from high-fidelity haemodynamic monitoring data.

Acute kidney injury is a common postoperative complication of paediatric cardiac surgery associated with increased morbidity and mortality. The purpose of this study is to characterise associations between haemodynamic parameters, clinical parameters, and medical interventions, on acute kidney injury. Nine patients with univentricular physiology undergoing the Norwood procedure from a single-centre tertiary care paediatric cardiac ICU were included (September 2022 to March 2023). Patients were monitored with the T3 software. Data were analysed using a Fisher exact test, Mann-Whitney-U test, LASSO-based machine learning techniques, and receiver operator curve analyses. Over 27,000 datapoints were included. Acute kidney injury occurred in 2 patients (22%) during this period. Net fluid balance and renal oxygen extraction were independently associated with acute kidney injury, while commonly used metrics of pressure (systolic, diastolic, or mean arterial blood pressure) were not. The resulting acute kidney injury risk score was (4.1 × fluid balance) + (1.9 × renal oxygen extraction). The risk score was significantly higher in acute kidney injury with a score of 32.9 compared to 7.9 (p < 0.01). Optimal cut-offs for fluid balance (7 mL/hr) and renal oxygen extraction (29%) were identified. Higher serum creatinine:baseline creatinine ratio was associated with a higher mean airway pressure, higher renal oxygen extraction, higher mean arterial blood pressure, higher vasoactive inotropic score, and fluid balance. Among patients with univentricular physiology undergoing the Norwood procedure, renal oxygen extraction and a higher net fluid balance are independently associated with increased risk of acute kidney injury. Renal perfusion pressure is not significantly associated with acute kidney injury.

Serum Homocysteine and Folic Acid Levels as Risk Factors of Chronic Kidney Disease

Chronic kidney disease (CKD) is a worldwide health problem. Homocysteine (Hcy) and folic acid (FA) have been found to correlate with intra-renal atherosclerosis, which leads to decreased renal perfusion pressure and may impair the endothelial function of renal arterioles and glomerular capillaries, thus being considered as new risk factors for CKD. Objective: To investigate serum Hcy and FA as risk factors for CKD. Methods: A cross-sectional study was conducted on 80 patients who underwent creatinine examination. Hcy and FA levels were examined using enzyme-linked immunosorbent assay (ELISA) method. Bivariate analysis to calculate the prevalence ratio (PR) using a 2x2 table and using Receiver Operating Characteristic (ROC) curves to determine the cut off value of HCY and FA in CKD. Results: The mean Hcy level of CKD patients was 7.66±4.25 µmol/L and without CKD was 4.29 ± 2.71 µmol/L. The mean FA levels of CKD and non-CKD patients were 6.75±1.75 and 9.27±9.28 ng/mL, respectively. The prevalence ratio of Hcy to CKD was 2.17 (95%CI=1.35-3.45; p=0.001). The prevalence ratio of FA to CKD was 1.75 (95%CI=1.11-2.75; p 0.014). Conclusion: Increased Hcy levels and decreased serum FA levels are risk factors for CKD.

Excess renin is attributed to the combination of forward and backward failure in HFrEF.

Regulation of the renin-angiotensin system (RAS) in heart failure (HF) with reduced ejection fraction (HFrEF) still raises questions, as a large proportion of patients show normal renin levels despite manifest disease. Experimental venous congestion results in reduced renal perfusion pressure and stimulates renin secretion. We hypothesized that excess renin levels are mainly a result of right ventricular failure as a sequalae of left ventricular dysfunction. The study aimed to link right ventricular function (RVF) with renin levels and to investigate further contributors to excess RAS activation. Three hundred thirty-two chronic HFrEF patients undergoing routine ambulatory care were consecutively enrolled in a prospective, registry-based, observational study. Laboratory parameters, including cardiac-specific markers renin, aldosterone, and N-terminal pro-brain natriuretic peptide (NT-proBNP), echocardiographic examination (n=247), and right heart catheterization (n=85), were documented. The relationship between renin and its respective parameters was analysed. Renin concentration was not associated with the New York Heart Association class or NT-proBNP. Systolic blood pressure, systemic vascular resistance, serum sodium, aldosterone, and lactate dehydrogenase were associated with increased renin levels (P<0.035 for all). Renin levels similarly increased with worsening of RVF parameters such as fractional area change, tricuspid annular plane systolic excursion, tissue Doppler imaging, and inferior vena cava diameter (P<0.011 for all), but not with pulmonary pressure. Excess renin levels were observed when worsening RVF was combined with reduced renal perfusion {625μIU/mL [interquartile range (IQR): 182-1761] vs. 67μIU/mL [IQR: 16-231], P<0.001}, which was associated with worse survival. While unrelated to classical indices of HF severity, circulating renin levels increase with the worsening of RVF, especially in the combined presence of forward and backward failure. This might explain normal renin levels in HFrEF patients but also excess renin levels in poor haemodynamic conditions.

The Effect of Positive Pressure Ventilation on Acute Kidney Injury in COVID-19 Patients with Acute Respiratory Distress Syndrome: An Observational Study

Introduction: Acute kidney injury (AKI) is frequent in critically ill COVID-19 patients and is associated with a higher mortality risk. By increasing intrathoracic pressure, positive pressure ventilation (PPV) may reduce renal perfusion pressure by reducing venous return to the heart or by increasing renal venous congestion. This study’s aim was to evaluate the association between AKI and haemodynamic and ventilatory parameters in COVID-19 patients with ARDS. Methods: This is a single-centre retrospective observational study. Consecutive patients diagnosed with COVID-19 who met ARDS criteria and required invasive mechanical ventilation were enrolled. The relationship between respiratory and haemodynamic parameters influenced by PPV and AKI development was evaluated. AKI was defined according to KDIGO criteria. AKI recovery was evaluated a month after ICU admission and patients were classified as “recovered,” if serum creatinine (sCr) value returned to baseline, or as having “acute kidney disease” (AKD), if criteria for AKI stage 1 or greater persisted. The 6-month all-cause mortality was collected. Results: A total of 144 patients were included in the analysis. AKI occurred in 69 (48%) patients and 26 (18%) required renal replacement therapy. In a multivariate logistic regression analysis, sex, hypertension, cumulative dose of furosemide, fluid balance, and plateau pressure were independently associated with AKI. Mortality at 6 months was 50% in the AKI group and 32% in the non-AKI group (p = 0.03). Among 36 patients who developed AKI and were discharged alive from the hospital, 56% had a full renal recovery after a month, while 14%, 6%, and 14% were classified as having an AKD of stage 0, 2, and 3, respectively. Conclusions: In our cohort, AKI was independently associated with multiple variables, including high plateau pressure, suggesting a possible role of PPV on AKI development. Further studies are needed to clarify the role of mechanical ventilation on renal function.

Transjugular intrahepatic portosystemic shunts for adults with hepatorenal syndrome.

Transjugular intrahepatic portosystemic shunts for adults with hepatorenal syndrome.

Transmission of high arterial pressure into renal microvessels during venous-clamping augments ischaemia/reperfusion-induced acute kidney injury in anaesthetized rats.

In two recent studies, we observed that a 30-min renal vein clamping caused formation of interstitial haemorrhagic congestion in ischaemic and ischaemic/reperfused kidney along with the development of severer acute kidney injury (AKI) than renal artery or pedicle clamping. It was suggested that the transmission of high arterial pressure into renal microvessels during vein occlusion probably causes the occurrence of interstitial haemorrhagic congestion that augments AKI. The present investigation aimed to evaluate this suggestion by reducing renal perfusion pressure (RPP) during renal venous occlusion. Anaesthetized male Sprague-Dawley rats were divided into three groups (n = 8), which underwent a 2-h reperfusion period following 30-min bilateral renal venous clamping along with reduced RPP (VIR-rRPP group) or without reduced RPP (VIR group) and an equivalent period after sham-operation (Sham group). The VIR-rRPP group compared with VIR group had lower levels of kidney malondialdehyde and tissue damages as epithelial injuries of proximal tubule and thick ascending limb, vascular congestion, intratubular cast and oedema, along with the less reductions in renal blood flow, creatinine clearance, Na+ -reabsorption, K+ and urea excretion, urine osmolality and free-water reabsorption. Importantly, the formation of intensive interstitial haemorrhagic congestion in the VIR group was not observed in the VIR-rRPP group. These results indicate that the transmission of high arterial pressure into renal microvessels during venous occlusion leads to rupturing of their walls and the formation of interstitial haemorrhagic congestion, which has an augmenting impact on ischaemia/reperfusion-induced renal structural damages and haemodynamic, excretory and urine-concentrating dysfunctions.

T-cells regulate albuminuria but not hypertension, renal histology, or the medullary transcriptome in the Dahl SSCD247+/+ rat.

In the current study, we took advantage of the loss of protection from hypertension in SSCD247-/- rats to characterize the pathological effects of renal T-cells in isolation from the confounding effects of elevated renal perfusion pressure. Male SSCD247-/- and SSCD247+/+ littermates were fed 4.0% NaCl (high salt) diet to induce hypertension. Blood pressure was assessed continuously throughout the time course with radiotelemetry. Urine albumin and protein excretion were assessed on the final day of high salt. Renal injury and medullary transcriptome were assessed after completion of the high salt protocol. In contrast to previous studies, mean arterial pressure was not significantly different between SSCD247-/- and SSCD247+/+ rats. Despite this lack of pressure difference, urinary albumin was significantly lower in SSCD247-/- rats than their wild-type littermates. In the outer medulla, substantially more transcriptomic changes were found to correlate with endpoint blood pressure than with the absence of presence of renal T-cells. We also demonstrated that renal histological damage was driven by elevated renal perfusion pressure rather than the presence of renal T-cells. In conclusion, using the loss of protection from hypertension in SSCD247-/- rats, we demonstrated that renal perfusion pressure has more profound pathological effects on the kidney than renal T-cells. However, renal T-cells, independently of blood pressure, modulate the progression of albuminuria.NEW & NOTEWORTHY In vivo studies in a T-cell-deficient rat model of salt-sensitive hypertension (SSCD247-/- rats) were used to evaluate the role of T-cells on the development of hypertension and renal damage. Detailed physiological and transcriptomic analysis demonstrated no difference in blood pressure between rats with (SSCD247+/+) or without (SSCD247-/-) T-cells. Despite this, albuminuria was significantly lower in SSCD247-/- rats than SSCD247+/+ rats.

Angiotensin II in liver transplantation (AngLT-1): protocol of a randomised, double-blind, placebo-controlled trial

IntroductionCatecholamine vasopressors such as norepinephrine are the standard drugs used to maintain mean arterial pressure during liver transplantation. At high doses, catecholamines may impair organ perfusion. Angiotensin II is a...

Prenatal diagnosis and treatment for fetal angiotensin converting enzyme deficiency.

To elucidate an etiology in a case with persistent oligohydramnios by prenatal diagnosis and actively treat the case to achieve good prognosis. We performed whole exome sequencing (WES) of DNA from the fetus and parents. Serial amnioinfusions were conducted until birth. Pressors were required to maintain normal blood pressure. The infant angiotensin-converting enzyme (ACE) activity, angiotensin II (Ang II, a downstream product of ACE), and compensatory enzymes (CEs) activities were measured. Compensatory enzyme activities in plasma from age-matched healthy controls were also detected. We identified a fetus with a severe ACE mutation prenatally. The infant was born prematurely without pulmonary dysplasia. Hypotension and anuria resolved spontaneously. He had almost no ACE activity, but his Ang II level and CE activity exceeded the upper limit of the normal range and the upper limit of the 95% confidence interval of controls, respectively. His renal function also largely recovered. Fetuses with ACE mutations can be diagnosed prenatally through WES. Serial amnioinfusion permits the continuation of pregnancy in fetal ACE deficiency. Compensatory enzymes for defective ACE appeared postnatally. Renal function may be spared by preterm delivery; furthermore, for postnatal vasopressor therapy to begin, improving renal perfusion pressure before nephrogenesis has been completed.

A Decrease in Effective Renal Perfusion Pressure Is Associated With Increased Acute Kidney Injury in Patients Undergoing Cardiac Surgery.

This study aimed to evaluate the relationship between intra-abdominal pressure (IAP), renal perfusion indices, and postoperative acute kidney injury (AKI) in cardiac patients. In a prospective cohort study conducted at a single academic institution, we collected data from adult patients undergoing open-heart operations with cardiopulmonary bypass (CPB) at our institution from February 2022 to April 2022 using the Accuryn SmartFoley system® (Potrero Medical, Hayward, CA). Patients on mechanical support devices, pregnant patients, and patients on hemodialysis were excluded. Demographics, hemodynamics, and mean airway pressure (mAir) were measured at the beginning of the cardiac operations and during the first four hours of ICU. Renal perfusion indices were then calculated (mean perfusion pressure (MPP) = mean arterial pressure (MAP) - central venous pressure (CVP); abdominal perfusion pressure (APP) = MAP - IAP; and effective renal perfusion pressure (eRPP) = MAP - (CVP + mAir + IAP)). Length of stay (LOS) was measured from the day of surgery to ICU discharge (ICU LOS) and hospital discharge (hospital LOS). During the first four hours of ICU stay, the non-AKI group had lower IAP and higher renal perfusion indices (MPP, APP, and eRPP). Logistic regression showed high perfusion pressures correlated with lower postoperative AKI (all OR <1, p<0.05). The postoperative AKI group also had significantly longer ICU LOS (7.33 vs. 4.57 days) and hospital LOS (17.0 vs. 10.2 days). Renal perfusion indices are a promising tool to predict postoperative AKI in cardiac surgery patients.

Abstract P397: Preservation Of Renal Microvascular Function In Ischemia-reperfusion Induced Kidney Injury In Rats

Proper renal blood flow and glomerular filtration rate are critical for maintaining normal kidney function by precisely adjusting preglomerular microvascular resistance. Renal ischemia-reperfusion (IR) insult markedly increased mRNA expression of the inflammatory chemokine (C-C motif) Ligand 2 (CCL2) in rat kidney tissues. We hypothesized that depletion of macrophages prevented IR-induced renal autoregulatory impairment via reduction of CCL2 in preglomerular microvessels (PGMV). IR was induced in male rats by 60-minute bilateral renal artery occlusion followed by reperfusion. Some IR rats were treated with the selective macrophage inhibitor, Liposome-encapsulated clodronate (LC) following reperfusion and repeated 72 hours post-IR. Afferent arteriolar autoregulatory reactivity was assessed using the in vitro blood-perfused juxtamedullary nephron preparation in sham, IR, and IR+LC rats on day 7. Afferent arterioles from sham-operated rats exhibited pressure-dependent vasoresponsiveness. The baseline arteriolar diameter averaged 13.4 ± 0.5 μm at renal perfusion pressure (RPP) of 100 mmHg. Diameter increased to 117 ± 4% of baseline at RPP of 65 mmHg and decreased to 69 ± 2% at 170 mmHg, respectively. In contrast, afferent arterioles from IR rats only increased to 104 ± 2% and decreased to 91 ± 5% of baseline at 65 and 170 mmHg, respectively (P &lt; 0.05 vs sham), indicating the impaired autoregulatory capacity in IR rats. LC-treated IR rats, however, markedly improved the pressure-dependent vasoresponsiveness. A decrease in RPP to 65 mmHg resulted in a 124 ± 17% increase in the baseline diameter, whereas increasing RPP to 170 mmHg led to a 74 ± 7% decrease in diameter. Additionally, IR markedly increased CCL2 mRNA expression in isolated PGMV by 10-fold 7 days post-IR. IR also elevated NADPH oxidase subunits (gp91 phox , P67 phox , and P47 phox ). Significantly, LC treatment suppressed mRNA expression of CCL2, gp91 phox , P67 phox , and P47 phox in IR-PGMV. In conclusion, depletion of macrophages preserves afferent arteriolar autoregulatory capacity and reduces PGMV CCL2 mRNA expression in IR rats, suggesting a critical role of macrophages in mediating renal microvascular autoregulatory impairment in IR-induced kidney injury via the increase of CCL2 in PGMV.

The role of Mas receptor on renal hemodynamic responses to angiotensin II administration in chronic renal sympathectomized male and female rats.

Renal hemodynamics is influenced by renal sympathetic nerves and the renin-angiotensin system. On the other hand, renal sympathetic denervation impacts kidney weight by affecting renal hemodynamics. The current study evaluated the role of the Mas receptor on renal hemodynamic responses under basal conditions and in response to angiotensin II (Ang II) in chronic renal sympathectomy in female and male rats. Forty-eight nephrectomized female and male rats were anesthetized and cannulated. Afterward, the effect of chronic renal sympathectomy was investigated on hemodynamic parameters such as renal vascular resistance (RVR), mean arterial pressure (MAP), and renal blood flow (RBF). In addition, the effect of chronic sympathectomy on kidney weight was examined. Chronic renal sympathectomy increased RVR and subsequently decreased RBF in both sexes. Renal perfusion pressure also increased after sympathectomy in male and female rats, while MAP did not change, significantly. In response to the Ang II injection, renal sympathectomy caused a greater decrease in RBF in all experimental groups, while it did not affect the MAP response. In addition, chronic sympathectomy increased left kidney weight in right nephrectomized rats. Chronic renal sympathectomy changed systemic/renal hemodynamics in baseline conditions and only renal hemodynamics in response to Ang II administration. Moreover, chronic sympathectomy increased compensatory hypertrophy in nephrectomized rats. These changes are unaffected by gender difference and Mas receptor blocker.

Age- and Gender-Related Differences in Renal Vascular Responses to Angiotensin II in Rats: The Role of the Mas Receptor.

Renal hemodynamic is influenced by both gender difference and age. Also, the Mas receptor (MasR) as one of the depressor components of the renin-angiotensin system which has more expression in females could postpone some dysfunctions associated with age, although the association between MasR and age in renal vascular responses to angiotensin II (Ang II) in male and female rats was well undefined. Therefore, the current study examined the effects of age and sex on systemic and renal vascular responses to graded doses of Ang II in Wistar rats with or without MasR antagonists (A779). Anesthetized Wistar male and female rats with two age ranges of 8-12 and 24-28 weeks were exposed to cannulate venous and arterial vessels. After stability, mean arterial pressure (MAP), renal perfusion pressure (RPP), renal vascular resistance (RVR), and renal blood flow (RBF) were measured in response to the infusion of Ang II with or without A779. There were no significant differences in the base values of MAP, RPP, RBF, and RVR between the two genders in both the age ranges of 8-12 and 24-28 weeks. In addition, no significant gender difference was observed in the age ranges of the above mentioned parameters among the groups receiving vehicle or A779. Also, the infusion of vehicle or A779 could not significantly change the base values. On the other hand, the responses of RBF and RVR to Ang II revealed gender differences among 8-12-week groups (P < 0.05) but not in 24-28-week groups, while the blockade of MasR could not influence the responses in the age ranges. It was concluded that age could impress sex difference in RBF and RVR responses to Ang II infusion and that MasR alone could not participate in these responses. In other words, MasR is not active under normal and acutely elevated Ang II levels.