True Treatment-resistant Hypertension Research Articles

Medical Measures in Hypertensives Considered Resistant.

Patients with resistant hypertension are the group of hypertensive patients with the highest cardiovascular risk. All rules and guidelines for treatment of hypertension should be followed strictly to obtain blood pressure (BP) control in resistant hypertension. The mainstay of treatment of hypertension, also for resistant hypertension, is pharmacological treatment, which should be tailored to each patient's specific phenotype. Therefore, it is pivotal to assess nonadherence to pharmacological treatment as this remains the most challenging problem to investigate and manage in the setting of resistant hypertension. Once adherence has been confirmed, patients must be thoroughly worked-up for secondary causes of hypertension. Until such possible specific causes have been clarified, the diagnosis is apparent treatment-resistant hypertension (TRH). Surprisingly few patients remain with true TRH when the various secondary causes and adherence problems have been detected and resolved. Refractory hypertension is a term used to characterize the treatment resistance in hypertensive patients using ≥5 antihypertensive drugs. All pressor mechanisms may then need blockage before their BPs are reasonably controlled. Patients with resistant hypertension need careful and sustained follow-up and review of their medications and dosages at each term since medication adherence is a very dynamic process.

Nonadherence in Hypertension: How to Develop and Implement Chemical Adherence Testing.

Nonadherence to antihypertensive medication is common, especially in those with apparent treatment-resistant hypertension (true treatment-resistant hypertension requires exclusion of nonadherence), and its routine detection is supported by clinical guidelines. Chemical adherence testing is a reliable and valid method to detect adherence, yet methods are unstandardized and are not ubiquitous. This article describes the principles of chemical adherence testing for hypertensive patients and provides a set of recommendations for centers wishing to develop the test. We recommend testing should be done in either of two instances: (1) in those who have resistant hypertension or (2) in those on 2 antihypertensives who have a less than 10 mm Hg drop in systolic blood pressure on addition of the second antihypertensive medication. Furthermore, we recommend that verbal consent is secured before undertaking the test, and the results should be discussed with the patient. Based on medications prescribed in United Kingdom, European Union, and United States, we list top 20 to 24 drugs that cover >95% of hypertension prescriptions which may be included in the testing panel. Information required to identify these medications on mass spectrometry platforms is likewise provided. We discuss issues related to ethics, sample collection, transport, stability, urine versus blood samples, qualitative versus quantitative testing, pharmacokinetics, instrumentation, validation, quality assurance, and gaps in knowledge. We consider how to best present, interpret, and discuss chemical adherence test results with the patient. In summary, this guidance should help clinicians and their laboratories in the development of chemical adherence testing of prescribed antihypertensive drugs.

SERUM CONC. OF ANTIHYPERTENSIVE DRUGS MAY REVEAL NON-ADHERENCE IN PATIENTS CONSIDERED TO HAVE TRUE TREATMENT RESISTANT HYPERTENSION ASSESSED BY DIRECTLY OBSERVED THERAPY

Objective: Detecting non-adherence is challenging. Both directly observed intake of antihypertensive medication (DOT) followed by 24 hour-ambulatory blood pressure monitoring and serum conc. measurements of antihypertensive drugs are objective methods considered reliable in revealing drug non-adherence. We aimed to investigate whether serum conc. offers additional information regarding drug adherence compared to DOT in patients with assumed true treatment resistant hypertension. Design and method: Patients referred for renal denervation (RDN) were thoroughly investigated and tested for adherence. 19 patients were defined as true treatment resistant when their daytime systolic BP remained high (> 135 mmHg) after DOT. Blood samples were collected at baseline, 6 months and 3 years after RDN and analyzed using ultra high pressure liquid chromatography-tandem mass spectrometry. Partial non-adherence was defined as at least one undetectable drug (but not all)and non-adherence as no detectable drugs in serum. Results: Ten out of 56 blood samples (17.9%) showed too low levels of one or more drug to be compatible with drug adherence. Six patients were redefined as either non-adherent or partially non-adherent based on their serum conc. results. Their systolic BPs are shown in the Figure. Three of these six patients went through a renal denervation procedure, while the remaining three were randomized to control. One of two patients considered to be RDN responders, became adherent to medication after six months which may have contributed to the fall in BP. At the 3 years visit none of the five antihypertensive agents prescribed were detected, and the patient́s BP was again elevated. Conclusions: Non-adherence was revealed in more patients when serum conc. measurements of antihypertensive drugs were added to directly observed therapy. Serum conc. measurement is objective and quantitative, and since some antihypertensive drugs require regular intake over a certain period of time to have maximal effect, they may offer important additional information.

Metabolic effects two years after renal denervation in insulin resistant hypertensive patients. The Re-Shape CV-risk study

Denervation of renal sympathetic nerves (RDN) is an invasive endovascular procedure introduced as an antihypertensive treatment with a potential beneficial effect on insulin resistance (IR). We have previously demonstrated a reduction in blood pressure (BP) six months after RDN, but severe hepatic and peripheral IR, assessed by glucose tracer and two step hyperinsulinemic-euglycemic clamp (HEC), did not improve. The aim of the current study was to evaluate IR and adipokines profiles in relation to BP and arterial stiffness changes two years after RDN. In 20 non-diabetic patients with true treatment-resistant hypertension, ambulatory and office BP were measured after witnessed intake of medications prior to, six and 24 months after RDN. Arterial stiffness index (AASI) was calculated from ambulatory BP. Insulin sensitivity (IS) was assessed using an oral glucose tolerance test (OGTT), the Homeostasis Model Assessment (HOMA-IR), HOMA-Adiponectin Model Assessment (HOMA-AD), the Quantitative Insulin Sensitivity Check Index (QUICKI), the Triglyceride and Glucose Index (TyG) and the Leptin-to-Adiponectin Ratio (LAR). These surrogate indices of IS were compared with tracer/HEC measurements to identify which best correlated in this group of patients. All measured metabolic variables and IS surrogate indices remained essentially unchanged two years after RDN apart from a significant increase in HOMA-AD. OGTT peak at 30min correlated best with reduction in endogenous glucose release (EGR) during low insulin HEC (r=-0.6, p=0.01), whereas HOMA-IR correlated best with whole-body glucose disposal (WGD) (r=-0.6, p=0.01) and glucose infusion rate (r=-0.6, p=0.01) during high insulin HEC. BP response was unrelated to IS prior to RDN. Nocturnal systolic BP and arterial stiffness before RDN correlated positively with a progression in hepatic IR at six-month follow-up. IR, adiponectin and leptin did not improve two years after RDN. There was no correlation between baseline IS and BP response. Our study does not support the notion of a beneficial metabolic effect of RDN in patients with treatment resistant hypertension.

Renal sympathetic denervation lowers systemic vascular resistance in true treatment-resistant hypertension

Purpose Renal sympathetic denervation (RDN) is again gaining interest as recent well-designed trials have demonstrated reduced ambulatory blood pressure (BP) after RDN. However, the hemodynamic mechanisms have not been elucidated. We aimed for the first time to investigate the effect of RDN on the “Hallmark of Hypertension” namely increased systemic vascular resistance index (SVRI). Materials and methods We investigated SVRI change in patients with true treatment-resistant hypertension randomised to RDN (n = 9) or drug adjusted control (n = 9). Treatment-resistant hypertension was defined as office systolic BP ≥ 140 mmHg despite ≥ 3 antihypertensive drugs including a diuretic. True treatment-resistant hypertension was confirmed prior to inclusion with ambulatory daytime systolic BP ≥ 135 mmHg immediately after witnessed intake of antihypertensive drugs. Hemodynamic variables were recorded with thoracic impedance cardiography at baseline and at three and six months follow-up after RDN. This non-invasive method also guided further tailoring of drug treatment in the control group aiming to normalise hemodynamic variables and BP. Results From three to six months follow-up after RDN, SVRI decreased with a median of −611 dyn*s*m2/cm5 [IQR −949 to −267] (p < 0.01), while supine mean BP decreased with a median of −11 mmHg [IQR −21 to −3] (p = 0.02). In the same period, SVRI in the control group was reduced with −674 dyn*s*m2/cm5 [IQR −1,309 to −340] (p < 0.01), while supine mean BP decreased with −15 mmHg [IQR −29 to −6] (p = 0.01). Thus, hemodynamic variables and BP in the two groups normalised in parallel. Conclusion Our data suggest that in patients with true treatment-resistant hypertension, renal sympathetic denervation lowers BP by reducing systemic vascular resistance of similar size as in the control group with careful individual selection of antihypertensive drugs and dose titration.

Measuring adherence to therapy in apparent treatment-resistant hypertension: a feasibility study in Irish primary care.

Apparent treatment-resistant hypertension (aTRH) is defined as uncontrolled blood pressure (BP) in patients taking three or more antihypertensive medications. Some patients will have true treatment-resistant hypertension, some undiagnosed secondary hypertension, while others have pseudo-resistance. Pseudo-resistance occurs when non-adherence to medication, white-coat hypertension (WCH), lifestyle, and inadequate drug dosing are responsible for the poorly controlled BP. To examine the feasibility of establishing non-adherence to medication, for the first time in primary care, using mass spectrometry urine analysis. Operationalisation would be established by at least 50% of patients participating and 95% of samples being suitable for analysis. Clinical importance would be confirmed by >10% of patients being non-adherent. Eligible patients with aTRH (n = 453) in 15 university research-affiliated Irish general practices were invited to participate. Participants underwent mass spectrometry urine analysis to test adherence and ambulatory BP monitoring (ABPM) to examine WCH. Of the eligible patients invited, 52% (n = 235) participated. All 235 urine samples (100%) were suitable for analysis: 174 (74%) patients were fully adherent, 56 (24%) partially adherent, and five (2%) fully non-adherent to therapy. A total of 206 patients also had ABPM, and in total 92 (45%) were categorised as pseudo-resistant. No significant associations were found between adherence status and patient characteristics or drug class. In patients with aTRH, the authors have established that it is feasible to examine non-adherence to medications using mass spectrometry urine analysis. One in four patients were found to be partially or fully non-adherent. Further research on how to incorporate this approach into individual patient consultations and its associated cost-effectiveness is now appropriate.

LONG-TERM OUTCOME OF THE RANDOMIZED OSLO-RDN STUDY

Objective: The blood pressure (BP) lowering effect of renal sympathetic denervation (RDN) in treatment resistant hypertension (TRH) shows variation among the few randomized studies. The duration of antihypertensive effect and long-term effect and safety of RDN requires further follow-up. We aimed to report the office, ambulatory blood pressure changes as well as long-term safety at 3 years follow-up in our Oslo-RDN study.Design and method: Patients with apparent TRH (n = 65) were referred specifically for RDN and those with secondary and spurious hypertension (n = 26) were excluded. TRH was defined as office systolic BP > 140 mmHg despite maximally tolerated doses of at least 3 antihypertensive drugs including a diuretic. Furthermore, ambulatory daytime systolic BP > 135 mmHg following witnessed intake of antihypertensive drugs was required. This procedure revealed that 20 patients had normalized BP, indicating poor adherence, and these patients were excluded. Patients with true TRH were randomized and underwent RDN with Symplicity catheter (n = 9) versus adjusted drug treatment (n = 10). Patients came for follow-up 3–4 years after baseline. Results: 24-hour ambulatory systolic and diastolic BPs in the drug adjustment group changed from 151 ± 13/84 ± 7 mmHg at baseline to 132 ± 15/77 ± 6 mmHg at 3-years, and in the RDN group from 149 ± 9/89 ± 7 mmHg at baseline to 137 ± 13/81 ± 10 mmHg at 3-years follow-up. Office, daytime and nighttime ambulatory BPs changed in parallel to the 24-hour ambulatory BPs. The absolute differences in systolic or diastolic BPs between the groups were consistent with earlier follow up points with a tendency toward a smaller difference between the groups. The difference in systolic BP at long-term follow up was not significant (p = 0.34). There were no significant changes in renal arteries assessed by MRI or CT scans at long-term follow-up. No deterioration of renal function was observed. Conclusions: The results at the three-year follow-up are consistent with earlier time points, with a tendency toward a smaller difference in BPs between the TRH and RDN groups. Our data support that RDN is a safe procedure on long-term follow-up and this allows further research to identify characteristics of patients who might respond to RDN.

Current Status of Renal Denervation in Hypertension.

Over the past 7years, prospective cohorts and small randomized controlled studies showed that renal denervation therapy (RDN) in patients with resistant hypertension is safe but associated with variable effects on BP which are not substantially better than medical therapy alone. The failure of the most rigorously designed randomized sham-control study, SYMPLICITY HTN-3, to meet the efficacy endpoints has raised several methodological concerns. However, recently reported studies and ongoing trials with improved procedural characteristics, identification of patients with true treatment-resistant hypertension on appropriate antihypertensive regimens further explore potential benefits of RDN. The scope of this review is to summarize evidence from currently completed studies on RDN and discuss future perspectives of RDN therapy in patients with resistant hypertension.

BR 04-1MANAGEMENT OF TREATMENT-RESISTANT HYPERTENSION

Treatment-resistant hypertension (TRH) is defined as the failure to achieve an office BP target of 10%, these levels may be inflated by white-coat hypertension and poor adherence. Indeed, PATHWAY-2 (Williams et al., Lancet 2016) and SYMPLICITY HNT-3 (Bhatt et al., NEJM 2014) suggest that true TRH is rarer than generally thought. Risk factors for TRH (which themselves increase cardiovascular risk) include obesity, older age, African ethnicity, CKD and diabetes. Although not fully addressed, evidence suggests that prolonged poorly controlled BP in TRH has a poor outcome. Before diagnosing TRH, pseudo-resistant HT must be excluded. Poor adherence to treatment – which may be caused by side-effects, complicated dosing schedules, pill burden, poor doctor-patient relationship, poor understanding or acceptance of the need for treatment, and medication cost –is common, with up to 40% of newly diagnosed hypertensive patients discontinuing medications within a year. Directly observed therapy and urine drug screens can be very helpful in its detection. Poor office BP measurement technique is another common problem. Sufficient rest, use of the right cuff, and repeated automated measurement in a quiet setting, is critical. ABPM (or at least home BP measurement) is crucial to excluding ‘white coat’ HT. In those diagnosed with true TRH, modifiable causes must be excluded, including diet, drugs, secondary endocrine and renal causes, and sleep apnoea. In most cases, however, the aetiology of TRH is multifactorial and treatment aimed at multiple targets. Treatment of TRH includes appropriate life-style change (focused on diet, salt intake, exercise, weight), withdrawal or minimization of offending drugs (including alcohol), and the use of effective multi-drug regimens. Pre-existing drug treatment should ideally combine a thiazide-like diuretic (TLD), calcium channel blocker, and ACE inhibitor/ARB. Optimising diuretic use appears very important, so use of a long-acting TLD, such as chlortalidone or indapamide, may help. Loop diuretics should be considered in CKD patients. Low-dose spironolactone (25 mg, increased to 50 mg, once daily) or eplerenone (both mineralocorticoid receptor antagonists) are now guideline approved as suitable 4th line agents in patients with TRH. Their success may be accounted for by the elevated aldosterone levels frequently found in TRH, either through undetected primary hyperaldosteronism or because aldosterone secretion escapes renin-angiotensin system blockade. Vital new evidence for the effectiveness of spironolactone in TRH comes from PATHWAY-2 (Williams et al., Lancet 2016). This randomised double-blind crossover trial involved sequential treatment with spironolactone (n = 285), an α1 blocker doxazosin (n = 282), β blocker bisoprolol (n = 285) and placebo (n = 274), each for 12 weeks. Spironolactone led to significantly greater mean reductions in systolic blood pressure than placebo (−10 [−11.7 to −8.74] mmHg, p An alternative promising approach is the use of endothelin (ET) receptor antagonists. These drugs, which block the vasoconstrictor, inflammatory and pro-atherogenic actions of ET-1, also reduce BP and proteinuria in CKD (Davenport et al., Pharmacol Rev 2016). Clinical trials have shown their efficacy in TRH (Weber et al., Lancet 2009), and phase 3 trials are currently ongoing in patients with diabetic nephropathy. Other drugs, such as b-blockers, a-blockers, centrally acting agents such as moxonidine or potent vasodilators, including hydralazine or minoxidil, may be considered in a multi-drug approach, depending on the clinical circumstances. The only combination that cannot be recommended is the addition of a second agent to block the renin-angiotensin system, with evidence of increased renal failure with the combination of ACE-I + ARB or ARB + renin inhibitor. Two promising non-pharmacological therapies have been under evaluation for the treatment of TRH – renal denervation (RDN) and baroreflex activation therapy (BAT). These are attractive targeted interventional options, with considerable underpinning evidence that sympathetic overactivity contributes to raised BP. However, when the first blinded and randomised study with RDN was performed, SYMPLICITY HNT-3 (Bhatt et al., NEJM 2014), it did no better than the sham procedure. Technically, it will be significantly easier to do randomised and blinded studies with BAT. However, currently, given their potential for adverse effects, and the lack of evidence of efficacy, RDN and BAT should only be used in the context of ongoing clinical research. This is an exciting time in the management of TRH. Spironolactone shows clear superiority to other standard treatments, and supports the case for excess sodium as a component of TRH. Other agents, such as ET antagonists, show promise. The results of SPRINT (The SPRINT Research Group, NEJM 2015) suggest we may need new lower targets for BP control, so TRH will become an increasing challenge. We also need good research on the risks of TRH, and what target blood pressures provide optimal outcomes.

PS 11-83 ONE-YEAR OUTCOMES OF THE RANDOMIZED OSLO-RDN STUDY

Objective: The blood pressure (BP) lowering effect of renal sympathetic denervation (RDN) in treatment resistant hypertension (TRH) shows variation among the few randomized studies. The duration of antihypertensive effect and long-term effect and safety of RDN require further follow-up. We aimed to report the office and ambulatory (BP) changes and long-term safety at 12-month follow-up. Design and Method: Patients with apparent TRH (n = 65) were referred specifically for RDN and those with secondary and spurious hypertension (n = 26) were excluded. TRH was defined as office systolic BP>140 mmHg despite maximally tolerated doses of at least 3 antihypertensive drugs including a diuretic. Additionally, ambulatory daytime systolic BP > 135 mmHg following witnessed intake of antihypertensive drugs was required, after which 20 patients had normalized BP, indicating poor drug adherence. Patients with true TRH were randomized and underwent RDN with Symplicity catheter (n = 9) versus adjusted drug treatment (n = 10). Results: 24-hour ambulatory systolic and diastolic BPs in the drug adjustment group changed from 151 ± 13/84 ± 7 mmHg (±SD) at baseline to 131 ± 12/75 ± 5 mmHg at 12 months (p < 0.0005 for all), and in the RDN group from 149 ± 9/89 ± 7 to 141 ± 11/83 ± 5 mmHg (p = 0.07 and p = 0.04, respectively). The absolute difference in change between groups in systolic BP was significantly higher in favor of the drug adjustment group (p = 0.01). Office, daytime and nighttime ambulatory BPs changed in parallel to the 24-hour ambulatory BPs. However 2 patients in RDN group considered as a responder since they have sustained reduction of 24-hour ambulatory systolic BP by more than 15 mmHg. There were no significant changes in renal arteries assessed by MRI or CT scans after 12 months follow-up. No deterioration of renal function was found. Conclusions: RDN has inferior BP lowering effects compared to adjusted drug treatment in patients with TRH. However, RDN is safe and this encourages future research to identify characteristics of patients who might respond to RDN.

Tertiary work-up of apparent treatment-resistant hypertension

Objective: Treatment-resistant hypertension (TRH) has regained attention with development of new methods for treatment. However, the prevalence of TRH varies considerably from primary to secondary and tertiary care. We aimed to assess the prevalence of true TRH in a population of patients with apparent TRH in a university hospital setting of tertiary work-up and also investigate reasons for poor BP control and evaluate how work-up can be performed in general practice and secondary care.Methods: In this cohort study, we characterize a study population from Oslo Renal Denervation (RDN) Study. Patients (n = 83) were referred for RDN from secondary care. All patients underwent thorough medical investigation and 24-h ambulatory blood pressure measurements (24ABPM) after directly observed therapy (DOT). We then assessed reasons for lack of BP control.Results: Fifty-three of 83 patients did not have true TRH. Main reasons for non-TRH were poor drug adherence (32%), secondary hypertension (30%) and white coat hypertension (15%). Forty-seven percent achieved blood pressure control after DOT with subsequent 24ABPM. There were otherwise no statistically significant differences in patient characteristics between the true TRH and the non-TRH group.Conclusion: Despite being a highly selected cohort referred for tertiary work-up of apparent TRH, BP control was achieved or secondary causes were identified in almost two thirds of the patients. Thorough investigation according to guidelines and DOT with subsequent 24ABPM is needed in work-up of apparent TRH.

Abstract 13281: Effect of Arteriovenous Anastomosis on Blood Pressure Reduction in Patients With Isolated Systolic Hypertension Compared to Combined Hypertension

Background: Several interventional therapeutic options for blood pressure (BP) lowering in patients with treatment-resistant hypertension (TRH) were introduced, such as renal denervation (RDN) and creation of an arteriovenous (AV) anastomosis using the ROX coupler. It was shown that BP response after RDN is greater in patients with combined hypertension (CH) compared to patients with isolated systolic hypertension (ISH). We analyzed now the effect of ROX coupler implantation in the subgroups with CH and ISH. Methods: The randomized, controlled, ROX CONTROL HTN study included patients with true TRH (office systolic BP ≥140mmHg, and average daytime ambulatory BP ≥135/85mmHg, despite treatment with at least 3 antihypertensive drugs including a diuretic). In our post-hoc analysis we have stratified the patients of the ROX coupler group (n=42) according CH (n=31) versus ISH (n=11). Results: Baseline systolic office (177±18 versus 169±17 mmHg, p=0.163) and ambulatory BP (159±16 versus 154±11 mmHg, p=0.463) did not differ between CH and ISH. Creation of an AV anastomosis resulted in a significant reduction in systolic office (CH: -28±22 versus ISH: -22±31 mmHg, p=0.572) as well as ambulatory BP (CH: -14±20 versus ISH: -13±15 mmHg, p=0.672), but without significant differences between the two subgroups. The non-responder rate (systolic office BP reduction &lt; 10 mmHg) after 6 months was not different between the subgroups (CH: 18 % versus ISH: 23 %, p=0.844). Conclusions: Thus, our data suggest that creation of an AV anastomosis using the ROX coupler reduces systolic office and ambulatory BP, without any significant difference between CH and ISH. In contrast to RDN, creation of an AV anastomosis reduced BP to similar extent in both subtypes of TRH.

Mid-Term Vascular Safety of Renal Denervation Assessed by Follow-up MR Imaging.

Renal denervation (RDN) emerged as a treatment option for reducing blood pressure (BP) in patients with treatment-resistant hypertension (TRH). However, concerns have been raised regarding the incidence of late renal artery stenosis or thromboembolism after RDN. The goal of the current study was, therefore, to conduct a prospective clinical trial on the mid-term vascular integrity of the renal arteries and the perfusion of the renal parenchyma assessed by magnetic resonance imaging (MRI) in the follow-up after catheter-based RDN. In our single-centre investigator initiated study, 51 patients with true TRH underwent catheter-based RDN using the Symplicity Flex(TM) catheter (Medtronic Inc., Palo Alto, CA). Follow-up MRI was performed at a median of 11 months (interquartile range 6-18 months) after RDN on a 1.5T MR unit. High-resolution MR angiography (MRA) and MRI results were compared to the baseline digital angiography of renal arteries obtained at time of RDN. In case of uncertainties (N = 2) catheter angiography was repeated. Both office and 24-h ambulatory BP were significantly reduced 6 and 12 months after RDN. Renal function remained unchanged 6 and 12 months after RDN. In all patients, MRA excluded new or progression of pre-existing low grade renal artery stenosis as well as focal aneurysms at the sites of radiofrequency ablation. In none of the patients new segmental perfusion deficits in either kidney were detected on MRI. No vascular or parenchymal complications after radiofrequency-based RDN were detected in 51 patients followed up by MRI.

Patient Cases 2. A Patient with Apparent Resistant Hypertension

True treatment-resistant hypertension (TRH) is defined by specific criteria and a failure to response to initial therapy options does not necessarily mean that a patient has TRH. In this case, a 44-year-old male was discharged on a fixed combination of valsartan/hydrochlorothiazide (HCTZ) 160/125 mg/day after presenting to the emergency room with paraesthesia of the upper left limb and recording a blood pressure (BP) of 190/110 mmHg. The patient had a number of other cardiovascular (CV) risk factors, and was determined to be at high risk of developing type 2 diabetes mellitus and of CV death. Carvedilol and atorvastatin were added, but 24-h ambulatory BP monitoring (ABPM) showed persistent hypertension. After specialist assessment, the patient's antihypertensive regimen was switched to a fixed-dose combination of olmesartan/HCTZ in the morning and a fixed-dose combination of olmesartan/amlodipine in the evening. Repeat ABPM 6 weeks later showed better BP control then previous ABPM.

PP.26.28

Objective: Treatment resistant hypertension is a challenge for the physician and represents a substantial cardiovascular risk for patients. While many patients are referred to specialists for resistant hypertension, the true resistant subjects are hard to find. We aimed to report the reasons for noneligibility in the Oslo Renal Denervation (RDN)Study following directly observed therapy (DOT) of antihypertensive drugs prior to ambulatory blood pressure monitoring (ABPM). Design and method: Patients with apparent resistant hypertension (n = 83), supposed to fulfill the inclusion/exclusion criteria, which were similar, but not identical with the SYMPLICITY HTN-2 criteria, were referred for renal denervation. All patients went through a throrough clinical and laboratory work-up including screening for renovascular hypertension, renal disease, primary hyperaldosteronism, Cushing's syndrome and pheochromocytoma. Nonadherence to antihypertensive drugs and white coat hypertension were controlled for by directly observed therapy followed by ABPM. Results: The proportion of patients being noneligible for renal denervation according to our inclusion/exclusion criteria was 69.9 %. The main reasons for noneligibility were normalization of blood pressure following witnessed intake of antihypertensive drugs (DOT) (43.0 %). Those with high office blood pressure in our clinic, but without prior ABPM from their referring physician, who had normal ABPM after DOT, were labeled white coat hypertensives. However, the possibility of nonadherence even among these subjects cannot be ruled out.Conclusions: True treatment resistant hypertension is rare. Secondary and spurious hypertension can be revealed and treated when medical evaluation of the patients is done thoroughly and according to guidelines by hypertension specialists. Nonadherence seems to be the most common reason for uncontrolled hypertension and may be revealed by directly observed therapy (DOT) followed by ambulatory blood pressure.

LB02.02

Objective: Several interventional therapeutic options for blood pressure (BP) lowering in patients with treatment-resistant hypertension (TRH) were introduced, such as renal denervation (RDN) and creation of an arteriovenous (AV) anastomosis using the ROX coupler. It was shown that BP response after RDN is greater in patients with combined hypertension (CH) compared to patients with isolated systolic hypertension (ISH). We analyzed now the effect of ROX coupler implantation in the subgroups with CH and ISH. Design and method: The randomized, controlled, ROX CONTROL HTN study included patients with true TRH (office systolic BP >=140mmHg, and average daytime ambulatory BP >=135/85mmHg, despite treatment with at least 3 antihypertensive drugs including a diuretic). In our post-hoc analysis we have stratified the patients of the ROX coupler group (n = 42) according CH (n = 31) versus ISH (n = 11). Results: Baseline systolic office (177 ± 18 versus 169 ± 17 mmHg, p = 0.163) and ambulatory BP (159 ± 16 versus 154 ± 11 mmHg, p = 0.463) did not differ between CH and ISH. Creation of an AV anastomosis resulted in a significant reduction in systolic office (CH: −28 ± 22 versus ISH: −22 ± 31 mmHg, p = 0.572) as well as ambulatory BP (CH: −14 ± 20 versus ISH: −13 ± 15 mmHg, p = 0.672), but without significant differences between the two subgroups. The non-responder rate (systolic office BP reduction < 10 mmHg) after 6 months was not different between the subgroups (CH: 18 % versus ISH: 23 %, p = 0.844). Conclusions: Thus, our data suggest that creation of an AV anastomosis using the ROX coupler reduces systolic office and ambulatory BP, without any significant difference between CH and ISH. In contrast to RDN, creation of an AV anastomosis reduced BP to similar extent in both subtypes of TRH.

Renal Nerve Ablation for Resistant Hypertension

Sympathetic renal denervation, or renal nerve ablation (RNA), has become the new buzz word in hypertension and interventional cardiology. Recent advances in catheter-based approaches have allowed sympathetic fiber interruption through transvascular techniques that are minimally invasive and can be delivered expeditiously and safely. Radiofrequency (RF) energy sources are currently the preferred modalities, but other sources of energy, such as cryoablation, microwave, high-intensity focus ultrasound, and local neurotoxic agent infusion, are under intense investigation. Results thus far have been encouraging and offer promise for the future. The role of the sympathetic nervous system (SNS) in the development of resistant hypertension and cardiovascular disease has long been known, and a great deal of work has been done through the years trying to explore potential interventions to interrupt the sympathetic influence on systemic vasculature and target organs. In this article we attempt an overview of time-dependent interventions on the SNS and examine approaches used in humans and in the many experimental models that offer a better understanding of the role of sympathetic activity in cardiovascular disease. Naturally we focus on methods and techniques addressing sympathetic renal denervation in patients with drug-resistant hypertension, examine the current state of the art, and attempt a look into the future. In 1889, after meticulous experiments on dogs, Bradford1 reported that stimulation of dorsal and splanchnic nerves causes changes in blood pressure (BP) and kidney size measured by plethysmography. Whether BP increased or decreased depended on the anatomic area stimulated, as well as the electric impulse frequency, but outcomes were consistent and reproducible. Neurosurgical treatment of hypertension was independently suggested by researchers in 1923.2 Adson, however, was the first to performed surgical sympathectomy for the treatment of malignant hypertension in 1925.3 During the following years and in the 1930s, Peet in Ann Arbor, Page and …

Adjusted Drug Treatment Is Superior to Renal Sympathetic Denervation in Patients With True Treatment-Resistant Hypertension

We aimed to investigate for the first time the blood pressure (BP)-lowering effect of renal sympathetic denervation (RDN) versus clinically adjusted drug treatment in true treatment-resistant hypertension (TRH) after excluding patients with confounding poor drug adherence. Patients with apparent TRH (n=65) were referred for RDN, and those with secondary and spurious hypertension (n=26) were excluded. TRH was defined as office systolic BP (SBP) >140 mm Hg, despite maximally tolerated doses of ≥3 antihypertensive drugs including a diuretic. In addition, ambulatory daytime SBP >135 mm Hg after witnessed intake of antihypertensive drugs was required, after which 20 patients had normalized BP and were excluded. Patients with true TRH were randomized and underwent RDN (n=9) performed with Symplicity Catheter System versus clinically adjusted drug treatment (n=10). The study was stopped early for ethical reasons because RDN had uncertain BP-lowering effect. Office SBP and diastolic BP in the drug-adjusted group changed from 160±14/88±13 mm Hg (±SD) at baseline to 132±10/77±8 mm Hg at 6 months (P<0.0005 and P=0.02, SBP and diastolic BP, respectively) and in the RDN group from 156±13/91±15 to 148±7/89±8 mm Hg (P=0.42 and P=0.48, SBP and diastolic BP, respectively). SBP and diastolic BP were significantly lower in the drug-adjusted group at 6 months (P=0.002 and P=0.004, respectively), and absolute changes in SBP were larger in the drug-adjusted group (P=0.008). Ambulatory BPs changed in parallel to office BPs. Our data suggest that adjusted drug treatment has superior BP lowering effects compared with RDN in patients with true TRH. Clinical Trial Registration- URL: http://www.clinicaltrials.gov. Unique identifier: NCT01673516.

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Prevalence and clinical characteristics of patients with true resistant hypertension in central and Eastern Europe

Scanty information is available on the clinical characteristics of resistant hypertension in Central and East European countries. The Blood Pressure (BP) control rate and CArdiovascular Risk profilE (BP-CARE) study allowed us to assess the prevalence and the main clinical features of resistant hypertension in this population. The study was carried out in 1312 treated hypertensive patients living in nine Central and East European countries. Four hundred and twenty-three patients had apparent resistant hypertension, of whom 168 had pseudo-resistant hypertension (noncompliant/white-coat) and 255 were true treatment-resistant hypertension patients (TRH). Clinical BP values in TRH amounted to 157.4±16.9/91.8±10.0 mmHg despite the daily use of 3.6±0.7 drugs. Their 24-h BP values were 149.5±16.5/97.5±9.8 mmHg. Compared to controlled hypertensive patients (n=368) and uncontrolled nonresistant hypertensive patients (n=521), TRH were older with a greater prevalence of women. They showed a higher rate of previous cardiovascular events and a very high cardiovascular risk profile. Estimated glomerular filtration rate was significantly lower in TRH as compared to controlled hypertensive patients and uncontrolled nonresistant hypertensive patients. Overall, target organ damage was more frequently detected in TRH than in controlled hypertensive patients and uncontrolled nonresistant hypertensive patients. The factor most frequently associated with TRH was severity of hypertension followed by age, total cholesterol, BMI and history of heart failure. The present study provides evidence that the prevalence of TRH in Central and East European countries is similar to that found in Western Europe and USA. It also shows the very high cardiovascular risk of TRH and the elevated association of this condition with obesity, renal failure, organ damage and history of cardiovascular events.