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Renin

Renin is a key enzyme in the renin-angiotensin system, which plays a critical role in regulating blood pressure and fluid balance within the body.
It is produced by the juxtaglomerular cells of the kidney and acts to catalyze the conversion of angiotensinogen to angiotensin I, the first step in the pathway that ultimately leads to the production of the potent vasoconstrictor angiotensin II.
Renin levels are often elevated in conditions such as hypertension, kidney disease, and heart failure, making it an important target for pharmacological interventions.
Reserach into novel renin-targeting therapies and improved understanding of renin's physiological functions continue to be an active area of study in cardiovasular and renal physiology.

Most cited protocols related to «Renin»

1
Malignant Hypertension Induction in Cyp1a1-Ren-2 Rats
Cited 17 times
To induce malignant hypertension, Cyp1a1-Ren-2 rats were fed a diet containing 0.3% I3C for 11 days, which results in the development of malignant hypertension with markedly elevated circulating and tissue ANG II levels as we and others [14 (link)–18 (link)] have demonstrated. The sEH inhibitor c-AUCB was given at a dose of 26 mg/l in drinking water that was prepared freshly every third day as described previously [17 (link)]. Treatment with c-AUCB was started 48 h before feeding the diet with or without I3C. This dose of c-AUCB and the same treatment protocol for c-AUCB were used in our recent study in which we found that it significantly attenuated the development of malignant hypertension in Cyp1a1-Ren-2 transgenic rats and substantially increased tissue concentrations of EETs [17 (link)]. Animals who were exposed to AT1 receptor blockade received losartan in their drinking water (100 mg/l; Lozap, Zentiva, Prague, Czech Republic); previous studies have demonstrated that this dose of losartan prevents the development of hypertension in this model [25 (link),26 (link)]. On the day of the experiment (day 11 after induction of the renin gene) rats were prepared for acute renal functional studies and for details see the online Data Supplement, http://links.lww.com/HJH/A98.
The following experimental groups of Cyp1a1-Ren-2 transgenic rats were examined:
Honetschlägerová Z., Sporková A., Kopkan L., Husková Z., Hwang S.H., Hammock B.D., Imig J.D., Kramer H.J., Kujal P., Vernerová Z., Chábová V.Č., Tesař V, & Červenka L. (2011). Inhibition of soluble epoxide hydrolase improves the impaired pressure–natriuresis relationship and attenuates the development of hypertension and hypertension-associated end-organ damage in Cyp1a1-Ren-2 transgenic rats. Journal of hypertension, 29(8), 1590-1601.
Publication 2011
Animals Cytochrome P-450 CYP1A1 Diet Dietary Supplements High Blood Pressures Induction, Genetic Losartan Malignant Hypertension Rats, Transgenic Rattus norvegicus Renin Tissues Treatment Protocols
2
Hypertension Management with Home Monitoring
Cited 8 times
The PEAR study [17 (link)]http://clinicaltrials.gov/ct2/show/NCT00246519 was approved by the Institutional Review Board at each site, and all participants gave informed consent. At an initial consent and screening visit, trained study personnel administered standardized questionnaires, performed a limited physical examination, and obtained blood and urine samples for testing to establish eligibility for participation [11 (link)]. Participants were provided an automated sphygmomanometer (MicroLife 3 AC1-PC, Minneapolis MN), the adequacy of which has been previously validated [18 (link)], and withdrawn from previous antihypertensive drug therapy. The device was set to measure BP in triplicate with each activation and to store the average systolic and diastolic BPs and the time of each set of measurements. Participants were instructed to take readings daily in the seated position, one set of three readings in the morning upon arising from bed and a second set in the evening just before retiring. At subsequent study visits (prior to randomization and at the end of therapy), an additional set of three readings was obtained seated (> 5 minutes) in the office using the home monitor. In addition, 24-hour ambulatory BP recordings were obtained at these visits using Spacelabs (Redmond WA) ambulatory monitors, model 90207, the adequacy of which has been previously validated [19 (link)]. Participants were instructed to conduct their usual daily activities while wearing the monitor, which was set to record BP four times per hour during the day (6 AM to 10 PM) and twice per hour during the night (10 PM to 6 AM). The average (± standard deviation) number of ambulatory measurements was 67 ± 10 during daytime hours and 15 ± 3 during nighttime hours.
At the end of the drug-free washout period, fasting blood samples were drawn in the seated position after ambulation for measurement of plasma renin activity [11 (link)]. To qualify for randomization, the average home diastolic BP in the previous week had to be ≥85 mmHg (consisting of at least five morning and five evening sets of readings) and the average office diastolic BP ≥ 90 mmHg. Participants received either atenolol or hydrochlorothiazide, starting at 50 mg or 12.5 mg daily, respectively, for two weeks, after which, if BP remained > 120/70 mmHg, the doses were increased to 100 mg or 25 mg daily, respectively, for six additional weeks.
Turner S.T., Schwartz G.L., Chapman A.B., Beitelshees A.L., Gums J.G., Cooper-DeHoff R.M., Boerwinkle E., Johnson J.A, & Bailey K.R. (2012). Power to identify a genetic predictor of antihypertensive drug response using different methods to measure blood pressure response. Journal of Translational Medicine, 10, 47.
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Publication 2012
Antihypertensive Agents Atenolol BLOOD Diastole Eligibility Determination Ethics Committees, Research Hydrochlorothiazide Medical Devices Pears Pharmaceutical Preparations Pharmacotherapy Physical Examination Plasma Pressure, Diastolic Renin Sitting Sphygmomanometers Systole Therapeutics Urinalysis
3
Plasma Biomarkers Measurement Protocol
Cited 7 times
Plasma corin, ANP (as N terminus-ANP), BNP (as C terminus-BNP), cGMP, angiotensin II and aldosterone levels were measured by enzyme immunoassays according to the manufacturer’s protocols (USCN Life Science Inc., China; Phoenix Pharmaceuticals, Inc.,Burlingame, CA; Enzo Life Science Inc.,Farmingdale, NY, Abcam Inc.,Cambridge, MA). Renin activities in plasma samples were measured by cleavage of a fluorescence resonance energy transfer substrate using a SensoLyte 520 mouse renin assay kit (AnaSpec, Fremont,CA) that allows the direct assessment of renin activity [34 (link)].
Tripathi R., Sullivan R., Fan T.H., Wang D., Sun Y., Reed G.L, & Gladysheva I.P. (2017). Enhanced heart failure, mortality and renin activation in female mice with experimental dilated cardiomyopathy. PLoS ONE, 12(12), e0189315.
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Publication 2017
Aldosterone Angiotensin II Biological Assay Cyclic GMP Cytokinesis Enzyme Immunoassay Fluorescence Resonance Energy Transfer Mus Pharmaceutical Preparations Plasma Renin
4
Primary Aldosteronism Investigation in Taiwan
Cited 7 times
The present study was based on the Taiwan Primary Aldosteronism Investigation (TAIPAI) database and tissue bank16 (link)17 (link)18 (link). The database was constructed from June 2008 to March 2011 for quality assurance at 2 medical centers and their 3 affiliated hospitals and two local hospitals in different cities in Taiwan19 (link). Before confirmatory tests, all antihypertensive medications were discontinued for at least 21 days. Diltiazem and/or doxazosin were administered to control markedly high blood pressure when required1 (link). Patients with an abnormal aldosterone-renin ratio (ARR) were confirmed with PA by saline infusion tests, and subsequently underwent imaging studies for subtype identification (figures S1 and S2).
PA confirmation and subtype studies were established in hypertensive patients according to the standard protocol of TAIPAI59 , including adrenal venous sampling and NP-59 scintigraphy with SPECT-CT imaging16 (link)17 (link)18 (link)20 (link) (see the supplementary file). Patients who were diagnosed with family type I (FH-I)/GRA were excluded via long-range polymerase chain reaction, as described previously21 (link).
Wu V.C., Huang K.H., Peng K.Y., Tsai Y.C., Wu C.H., Wang S.M., Yang S.Y., Lin L.Y., Chang C.C., Lin Y.H., Lin S.L., Chu T.S, & Wu K.D. (2015). Prevalence and clinical correlates of somatic mutation in aldosterone producing adenoma-Taiwanese population. Scientific Reports, 5, 11396.
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Publication 2015
Aldosterone Antihypertensive Agents Conn Syndrome Diltiazem Doxazosin High Blood Pressures NP-59 Patients Polymerase Chain Reaction Radionuclide Imaging Renin Saline Solution Single Photon Emission Computed Tomography Computed Tomography Tissues Tomography, Emission-Computed, Single-Photon Veins X-Ray Computed Tomography
5
Angiotensin Peptides and Enzyme Assays
Cited 6 times
Blood was collected from participants in the seated position to obtain plasma renin activity, aldosterone, Ang II, and Ang-(1-7). For the peptide measurements, blood samples were collected immediately in a tube containing a cocktail of inhibitors and plasma was obtained and stored at −80 °C. The plasma was thawed on ice, extracted on Sep-Pak C18 columns (Waters Corp., Milford, Massachusetts, USA), and the eluted fractions assayed by an Ang II radioimmunoassay (RIA, Alpco, Salem, New Hampshire, USA; detection limit 0.8 pmol/l; intra-assay and inter-assay coefficients of variation 12 and 22%) and an Ang-(1-7) RIA (detection limit 2.8 pmol/l; intra-assay and inter-assay coefficients of variation 8 and 20%) [11 (link)]. Aldosterone content was determined in nonextracted plasma samples by RIA (Diagnostics Products, Los Angeles, California, USA; detection limit 28 pmol/l). Renin activity was directly determined in plasma samples using an RIA (Cisbio, Codolet, France; detection limit 4 pmol Ang I/l/hour). We calculated the Ang II-to-Ang-(1-7) ratio and the aldosterone-to-renin ratio for plasma samples.
Spot urine samples were collected, immediately acidified with HCl to prevent peptide degradation, and stored at −80 °C. The urine samples were thawed on ice, extracted on SepPak columns, and the urinary levels of Ang II and Ang-(1-7) quantified by RIAs. For the ACE and ACE2 assays, separate nonacidified urine samples were collected and were concentrated 10-fold on a Millipore 5000-Da cut-off filter with the assay buffer. ACE and ACE2 assays were conducted at 37 °C in 10 mmol/l of HEPES, 125 mmol/l of NaCl, and 10 µmol/l of ZnCl2 (pH 7.4), with 0.02 ml of urine in a final volume of 0.2 ml with the indicated inhibitors and 0.02 ml of 0.1 mmol/l of either the quenched fluorescent substrate Mca-RPPGFSAFK-DNP for ACE or Mca-APK-DNP for ACE2 in a 96-well black plate. The fluorescence was read in a plate reader at an excitation λ of 328 nm and an emission λ of 393 nm. Blanks consisted of the substrate alone and the addition of the ACE inhibitor lisinopril or the ACE2 inhibitor MLN4760 for the ACE and ACE2 assays, respectively.
As the ACE and ACE2 substrates are not specific, the assays contained inhibitors against aminopeptidases (bestatin 10 µmol/l), carboxypeptidase A (benzyl succinate 10 µmol/l), serine peptidases (chymostatin 10 µmol/l), cysteine peptidases (para-chloro-mercuribenzoic acid 0.5 mmol/l), neprilysin (SCH39370, 10 µmol/l), and lisinopril (10 µmol/l) to measure ACE2 or MLN4760 (10 µmol/l) to measure ACE. ACE and ACE2 protein content (ng/mg creatinine) were based on human ACE and ACE2 standards obtained from R&D Systems (Minneapolis, Minnesota, USA). Standard enzymes were assayed under the same conditions as the urine samples. Fluorescent substrates for ACE and ACE2 were obtained from Enzo Life Sciences (VWR, Atlanta, Georgia, USA).
Creatinine levels in nonextracted urine samples were determined by a modified Jaffe assay traceable to isotope dilution mass spectrometry [11 (link)]. We calculated the urinary Ang II:Ang-(1-7) and ACE:ACE2 ratios and corrected Ang II and Ang-(1-7) concentrations and ACE and ACE2 concentrations by urine creatinine. If blood or urine sample results were below the laboratory’s lower limit of detection, the sample’s measurement was assigned a value calculated as the lower limit of detection divided by the square root of two [31 ].
South A.M., Nixon P.A., Chappell M.C., Diz D.I., Russell G.B., Jensen E.T., Shaltout H.A., O’Shea T.M, & Washburn L.K. (2018). Association between preterm birth and the renin–angiotensin system in adolescence: influence of sex and obesity. Journal of hypertension, 36(10), 2092-2101.
Publication 2018
ACE2 protein, human Acids Aldosterone Aminopeptidase Angiotensin-Converting Enzyme Inhibitors Angiotensin Converting Enzyme 2 angiotensin I (1-7) Biological Assay BLOOD Buffers Carboxypeptidase A chymostatin Creatinine Cysteine Proteases DA10 Diagnosis Enzymes Fluorescence HEPES Homo sapiens inhibitors Isotopes Lisinopril Mass Spectrometry MLN 4760 Neprilysin Peptides Plant Roots Plasma Radioimmunoassay Renin Sep-Pak C18 Serine Endopeptidases Sitting Sodium Chloride Succinate Technique, Dilution ubenimex Urine

Most recents protocols related to «Renin»

1
Modeling Real-World RAASi Treatment Changes
In both treatment arms, all patients are initiated in the model on RAASi and are assumed to be receiving a maximum dose. Down-titration to a sub-maximal dose, or discontinuation of RAASi treatment (from any dose) may occur. RAASi use favourably impacts the progression of CKD and the incidence of MACE, hospitalisation and death (Fig. 2), with an increase in the incidence of HK; the magnitude of these impacts is further described in Supplemental Appendix A [23 (link), 36 (link)–42 (link), 46 (link)–50 ].
The proportion of patients still on RAASi at the end of the first month is specified for both arms and based on OPAL-HK trial data. For the patiromer arm, this proportion relates only to those that have achieved response, with the remaining patients assumed to be receiving RAASi therapy in line with the SoC arm. Rates of RAASi discontinuation and down-titration are taken from the OPAL-HK trial for months 2 and 3 [43 ]. From month 4 onwards, potassium level dependent RAASi discontinuation and down-titration rates were taken from Linde et al. (2019) and applied to the SoC arm [23 (link)]. Hazard ratios relating to reduced (or increased) rates of discontinuation/down-titration in those receiving patiromer in subsequent months were obtained from the OPAL-HK trial and applied to the rates from Linde et al. (2019). To reflect the impermanent nature of RAASi treatment changes in clinical practice, patients could return to optimal RAASi use independent of their potassium level with a monthly probability of 3.51% [23 (link)]. Due to a lack of relevant data, patients who down-titrated RAASi use were assumed to not return to maximum use. RAASi discontinuation and down-titration rates are summarised in Table 3.

RAASi discontinuation, down-titration and up-titration, by potassium category

Monthly probability of RAASi max discontinuation (%)Monthly probability of RAASi max down-titration (%)Monthly probability of RAASi sub-max discontinuation (%)Source
SoCPatiromerSoCPatiromerSoCPatiromer
Month 2–334.438% (6.589%)3.336% (2.421%)35.549% (6.589%)0.000% (0.000%)34.438% (6.589%)3.336% (2.421%)OPAL-HK [43 ]
Subsequent months
K +  ≤ 52.600% (0.009%)0.181%1.800% (0.026%)1.800%2.600% (0.009%)0.181%Linde et al. (2019) [23 (link)]
K +  > 5 to ≤ 5.53.029% (0.102%)0.211%2.617% (0.102%)2.617%3.029% (0.102%)0.211%
K +  > 5.5 to ≤ 64.547% (0.230%)0.319%5.306% (0.230%)5.306%4.547% (0.230%)0.319%
K +  > 610.000% (0.663%)0.721%8.900% (0.638%)8.900%10.000% (0.663%)0.721%

RAASi Renin–angiotensin–aldosterone system inhibitor, K + Potassium, SE Standard error, SoC Standard of care

Note: Complete derivation described further in Supplemental Appendix A

Ward T., Lewis R.D., Brown T., Baxter G, & de Arellano A.R. (2023). A cost-effectiveness analysis of patiromer in the UK: evaluation of hyperkalaemia treatment and lifelong RAASi maintenance in chronic kidney disease patients with and without heart failure. BMC Nephrology, 24, 47.
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Publication 2023
Aldosterone Aldosterone Antagonists Angiotensins Disease Progression Myristica fragrans Patients patiromer Potassium Renin Renin Inhibitors Titrimetry VPDA protocol
2
Modeling Hyperkalaemia Event Rates and Impacts
The occurrence of HK was categorized as a serum potassium level greater than 5 mmol/l, consistent with the definitions used in the OPAL-HK trial and widely accepted in the broader HK literature [29 (link), 44 (link)]. Events were further stratified by severity (i.e., 5–5.5 mmol/l, 5.5–6 mmol/l and > 6 mmol/l). During the first three months of the modelled time horizon, incident HK events are predicted based on data from the OPAL-HK trial [29 (link), 45 (link)]. For all subsequent months, annual rates of HK were obtained from Horne et al. (2019) and applied to the SoC arm [46 (link)]. Hazard ratios relating to reduced (or increased) incidence in those receiving patiromer in subsequent years were obtained from the OPAL-HK trial and applied to the annual rates of HK obtained from Horne et al. (2019). HK event rates are summarised in Table 2. Increased potassium levels negatively impact the incidence of MACE, hospitalisation and death (Fig. 2); the magnitude of these impacts is further described in Supplemental Appendix A.

HK incidence

Time appliedPotassium levelMonthly probabilitySource
PatiromerSoC
MeanSEMeanSE
Month 1K +  > 5 to ≤ 5.521.13%3.32%21.13%3.32%OPAL-HK CSR; distributed across threshold categories in line with published data [43 , 46 (link)]
K +  > 5.5 to ≤ 61.66%1.04%1.66%1.04%
K +  > 60.38%0.50%0.38%0.50%
Month 2 & 3K +  > 5 to ≤ 5.514.00%4.68%15.00%4.81%OPAL-HK CSR [43 ]
K +  > 5.5 to ≤ 66.10%3.23%25.22%5.86%
K +  > 61.40%1.58%5.78%3.15%
Subsequent monthsaK +  > 5 to ≤ 5.50.543%0.054%1.158%0.116%Horne et al. (2019); 'OPAL-HK CSR [43 , 46 (link)]
K +  > 5.5 to ≤ 60.022%0.002%0.092%0.009%
K +  > 60.005%0.001%0.021%0.002%

HK Hyperkalaemia, RAASi Renin–angiotensin–aldosterone system inhibitor, SE Standard error, SoC Standard of care

aSoC probabilities informed by HK recurrence rates observed in Horne et al. (2019) with recurrence events distributed in line with the distribution of initial HK events across potassium categories; patiromer estimates informed by Horne et al. (2019) after application of a HR based on OPAL-HK data from months 2 and 3; SE assumed as 10% of mean

Influence of RAASi use and HK events on disease progression and events. References below each box describe the baseline probabilities/rates; references alongside arrows describe the influence of one disease component on the other, with influences applied to the baseline probabilities rates

Ward T., Lewis R.D., Brown T., Baxter G, & de Arellano A.R. (2023). A cost-effectiveness analysis of patiromer in the UK: evaluation of hyperkalaemia treatment and lifelong RAASi maintenance in chronic kidney disease patients with and without heart failure. BMC Nephrology, 24, 47.
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Publication 2023
Aldosterone Aldosterone Antagonists Angiotensins Disease Progression Myristica fragrans patiromer Potassium Recurrence Renin Renin Inhibitors Serum VPDA protocol
3
Retrospective Analysis of Renal Artery Stenosis
A total of 3866 hypertensive patients with RAS referred to two tertiary referral centres in China, that is the National Center for Cardiovascular Diseases, Fuwai Hospital, Beijing, and the Department of Hypertension, Ruijin Hospital, Shanghai, between January 2000 and August 2022 were retrospectively analysed. All of the patients suffered from hypertension. Most of them were admitted for screening for the causes of hypertension and were first diagnosed as RAS at Fuwai or Ruijin Hospital. The remainder were referred to the centres for the treatment of RAS. Before being referred to the two central hospitals, the patients were diagnosed with RAS by renal computed tomography angiography (CTA) or renal artery Duplex.
Among all the RAS patients, 3209 (83.0%) were with atherosclerosis, 366 (9.5%) were with Takayasu disease and 46 (1.2%) were with other conditions. The remaining 245 (6.3%) patients met the diagnostic criteria for FMD and were subsequently included in the study.
All patients underwent a detailed investigation, including demographic characteristics (age, sex, height and ethnicity), clinical characteristics (office BP, smoking, family history of hypertension or FMD, concomitant diseases, current medications, age at diagnosis of FMD, an angiographic subtype of FMD, symptoms of FMD at diagnosis and associated atheroma lesions), biochemical sampling (plasma aldosterone, plasma renin activity), Doppler ultrasonography of carotid arteries, magnetic resonance angiography (MRA) of the intracranial artery and CTA or MRA of the abdominal and renal artery. All patients diagnosed with FMD underwent catheter-based angiography and balloon angioplasty to treat renovascular hypertension, and stent implantation should not be performed unless balloon angioplasty was failed.
The ethics committees of Fuwai Hospital, National Center for Cardiovascular Disease in Beijing and Ruijin Hospital, Shanghai Jiao Tong University School of Medicine in Shanghai approved their cohort study protocol, respectively. All participants gave written informed consent. The study was conducted in accordance with the Declaration of Helsinki.
Kang Y.Y., Chen Y., Wu Q.H., Dong H., Zou Y.B., Gao P.J., Xu J.Z., Jiang X.J, & Wang J.G. (2023). Prevalence and clinical characteristics of renovascular hypertension associated with fibromuscular dysplasia in China. Journal of Hypertension, 41(4), 638-647.
Publication 2023
Abdomen Aldosterone Angiography Angioplasty, Balloon, Coronary Arteries Atheroma Atherosclerosis Cardiovascular Diseases Catheters Computed Tomography Angiography concomitant disease Ethics Committees, Clinical Ethnicity High Blood Pressures Hypertension, Renovascular Kidney Magnetic Resonance Angiography Ovum Implantation Patients Pharmaceutical Preparations Plasma Renal Artery Renin Stents Takayasu Arteritis Ultrasonography, Carotid Arteries
4
Comprehensive Cardiovascular Assessment in Geriatric Patients
Patients’ demographic information, medical comorbidities, associated clinical data, and medications were extracted from the medical records in the geriatric cardiovascular department during the study period. Comorbidities, including diabetes mellitus, dyslipidemia, chronic kidney disease, coronary artery disease, chronic heart failure, and cerebrovascular disease, were determined on the basis of inpatient ICD‐9 diagnoses codes. Among these, chronic kidney disease was diagnosed by impaired glomerular filtration rates (< 60 ml/min/1.73 m2), or proteinuria (urinary albumin/creatinine ratio values ≥30 mg/g), persisting for more than 3 months. All participants underwent measurement of body mass index (BMI), serum urea, creatinine, uric acid, homocysteine, brain natriuretic peptide, spot urinary albumin/creatinine ratio, and brachial‐ankle pulse wave velocity (baPWV) during their hospitalization. Total 85.9% participants completed 24‐hour blood pressure monitoring and had effective data. Estimated glomerular filtration rates were estimated from serum creatinine levels and the Chronic Kidney Disease Epidemiology Collaboration equation.9 The baPWV was automatically measured by two trained researchers using form PWV/ABI instruments (form PWV/ABI, BP‐203RPE III; Omron‐Colin, Japan). Further screening for secondary hypertension, including serum potassium, renin, aldosterone, plasma metanephrine levels, thyroid function tests, 24‐h urinary potassium, renal artery ultrasound or computed tomography angiography, adrenal computed tomography scan or magnetic resonance imaging, and polysomnography, and so on, which was guided by history, clinical examination, and baseline laboratory data, was conducted in patients who were diagnosed as RHTN according to the latest guidelines.10 The diagnosis of secondary hypertension, including chronic kidney disease, obstructive sleep apnea, primary aldosteronism, renovascular disease were conducted according to the associated guidelines.11, 12, 13, 14For measurements of systemic hemodynamics, a CNAP™ monitor (CN Systems Medizintechnik AG, Graz, Austria), which is a continuous noninvasive arterial pressure measurement device, was used. The CNAP™ monitor has been validated for arterial BP, cardiac output, and other hemodynamics.15 Hemodynamic measurements were performed by two fixed trained researchers. An appropriately sized finger cuff of the CNAP™ monitor was affixed to each participant's finger, after a 5‐min supine resting period, and the measurement hand was placed on side of the body. The beat‐to‐beat measurements of systolic BP, diastolic BP, heart rate, cardiac output, and systemic vascular resistance of all participants were performed in the supine position.
Geng H., Chen X., Liang W, & Liu M. (2023). Associated factors and hemodynamic characteristics of resistant hypertension in the elderly. The Journal of Clinical Hypertension, 25(3), 259-265.
Publication 2023
Albumins Aldosterone Ankle Arteries Blood Pressure Cardiac Output Cardiovascular System Cerebrovascular Disorders Chronic Kidney Diseases Computed Tomography Angiography Conn Syndrome Coronary Artery Disease Creatinine Diabetes Mellitus Diagnosis Dyslipidemias Fingers Glomerular Filtration Rate Heart Failure Hemodynamics High Blood Pressures Homocysteine Hospitalization Human Body Inpatient Measure, Body Metanephrine Nesiritide Patients Pharmaceutical Preparations Physical Examination Plasma Polysomnography Potassium Pressure, Diastolic Radionuclide Imaging Rate, Heart Renal Artery Renin Serum Sleep Apnea, Obstructive Sphygmomanometers Systolic Pressure Thyroid Function Tests Total Peripheral Resistance Ultrasonography Urea Uric Acid Urine X-Ray Computed Tomography
5
Hypertension Cohort Study in Northeast Italy
One-hundred-twenty-eight consecutive patients with grade 1/grade 2 essential hypertension who presented at the outpatient service of our Clinic from January 2019 to December 2019 were included in a cross-sectional study. Patients seen at the Clinic are white, live in the North-East of Italy, and are representative of the hypertensive population of this regional territory (34 (link)). An automatic tool equipped with appropriately sized cuffs (Omron M6, OMRON Healthcare Co., Kyoto, Japan) was used to measure blood pressure in patients who had been supine for at least 15 min, obtaining 3 consecutive readings. According to current guidelines (35 (link)), diagnosis of hypertension was done after measurements obtained in at least 3 separate visits. Exclusion criteria were predefined as follows: age younger than 18 or older than 80 years; body mass index (BMI) greater than 35 kg/m2; pregnancy; secondary hypertension; 24-h creatinine clearance lower than 30 ml/min/1,73 m2; diabetes; use of lipid-lowering, antiplatelet, anticoagulant drugs and any type of drugs that could interfere with the hemostatic system; history of recent illness and acute or chronic inflammatory conditions; history of cerebrovascular, ischemic heart, or peripheral artery disease. Causes of secondary hypertension were ruled out according to current guidelines (35 (link)) after clinical, biochemical (urine analysis, creatinine clearance, plasma aldosterone, renin, and cortisol, free urinary cortisol and epinephrine, norepinephrine, and dopamine) and instrumental tests (ECG, echocardiography, renal ultrasound, and renal angio-CT and adrenal CT scan when indicated) (36 (link)). Diabetes was excluded by measurement of fasting blood glucose and glycated hemoglobin, and by a standard oral glucose tolerance test (37 (link)). Smokers were defined if they smoked for more than 5 years and did not quit more than 1 year before examination. Ethanol consumption (grams/day) was assessed by a standardized questionnaire (38 (link)). The leisure physical activity of all patients was estimated by a questionnaire, and patients that practiced at least 3 h of aerobic exercise in a week were defined as physically active. The study was conducted following the statements of the Declaration of Helsinki and was approved by the Institutional Review Board. All patients gave their informed consent.
Brosolo G., Da Porto A., Bulfone L., Vacca A., Bertin N., Vivarelli C., Sechi L.A, & Catena C. (2023). Association of arterial stiffness with a prothrombotic state in uncomplicated nondiabetic hypertensive patients. Frontiers in Cardiovascular Medicine, 10, 1119516.
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Publication 2023
Aldosterone Anticoagulants Blood Glucose Blood Pressure Chronic Condition Creatinine Diabetes Mellitus Diagnosis Dopamine Echocardiography Epinephrine Essential Hypertension Ethics Committees, Research Exercise, Aerobic Health Services, Outpatient Heart Hemoglobin, Glycosylated Hemostasis High Blood Pressures Hydrocortisone Index, Body Mass Inflammation Kidney Lipids Norepinephrine Oral Glucose Tolerance Test Patients Peripheral Arterial Diseases Pharmaceutical Preparations Physical Examination Plasma Pregnancy Renin Ultrasonography Urinalysis Urine Vision X-Ray Computed Tomography Youth

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Taqman gene expression assay by Thermo Fisher Scientific
Sourced in United States, Germany, United Kingdom, Japan, Switzerland, Canada, Italy, Australia, Spain, France, Sweden, Estonia, Lithuania, Belgium, Denmark, Finland, Israel, Netherlands, Hungary
TaqMan Gene Expression Assays are a set of pre-designed and pre-optimized qPCR assays for accurately quantifying gene expression levels. They provide a sensitive and reliable method for measuring targeted mRNA transcripts in a variety of sample types.
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Coat a count aldosterone by Siemens
Sourced in Germany, United States
Coat-a-Count Aldosterone is a laboratory equipment product used for the quantitative measurement of aldosterone levels in human serum or plasma samples. It is a radioimmunoassay-based test that provides accurate and reliable results for diagnostic purposes.

More about "Renin"

Renin, a crucial enzyme in the renin-angiotensin system (RAS), plays a pivotal role in regulating blood pressure and fluid balance within the body.
Produced by the juxtaglomerular cells of the kidney, renin catalyzes the conversion of angiotensinogen to angiotensin I, the first step in the pathway that ultimately leads to the formation of the potent vasoconstrictor angiotensin II.
Elevated renin levels are often observed in conditions such as hypertension, kidney disease, and heart failure, making it a crucial target for pharmacological interventions.
Researchers continue to explore novel renin-targeting therapies and gain a deeper understanding of renin's physiological functions in cardiovascular and renal physiology.
Tools like TRIzol reagent, RNeasy Mini Kit, and TaqMan Gene Expression Assays are commonly used to study renin gene expression and activity.
Meanwhile, techniques such as the SPAC-S Aldosterone Kit, Aldosterone ELISA Kit, and GammaCoat Plasma Renin Activity 125I RIA kit help researchers measure aldosterone and renin levels.
Captopril, a well-known angiotensin-converting enzyme (ACE) inhibitor, is also widely used to investigate the RAS and its impact on renin.
The LIAISON Direct Renin kit is a convenient tool for the direct measurement of renin concentration, providing valuable insights into the RAS.
PubCompare.ai, an innovative AI-powered platform, revolutionizes renin research by enabling effortless protocol comparisons and the identification of the best protocols and products from literature, pre-prints, and patents.
This intelligent tool helps researchers optimize their renin studies and advance the understanding of this critical enzyme and its role in cardiovascular and renal health.