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Joint UK societies’ 2014 consensus statement on renal denervation for resistant hypertension
  1. Melvin D Lobo1,2,3,
  2. Mark A de Belder4,5,6,
  3. Trevor Cleveland7,8,
  4. David Collier1,2,
  5. Indranil Dasgupta9,10,
  6. John Deanfield6,11,
  7. Vikas Kapil1,2,3,
  8. Charles Knight3,4,
  9. Matthew Matson7,2,
  10. Jonathan Moss7,12,
  11. Julian F R Paton1,13,
  12. Neil Poulter1,14,
  13. Iain Simpson4,15,
  14. Bryan Williams1,16,
  15. Mark J Caulfield1,2,3
  1. 1On behalf of the British Hypertension Society
  2. 2Barts NIHR Cardiovascular Biomedical Research Unit, William Harvey Research Institute, Queen Mary University of London, London, UK
  3. 3Department of Cardiovascular Medicine, Barts Health NHS Trust, London, UK
  4. 4The British Cardiovascular Society
  5. 5The British Cardiovascular Intervention Society
  6. 6Cardiothoracic Division, The James Cook University Hospital, Middlesbrough, UK
  7. 7The British Society for Interventional Radiology
  8. 8Sheffield Vascular Institute, Sheffield Teaching Hospitals NHSFT, Northern General Hospital, Sheffield, UK
  9. 9The Renal Association
  10. 10Department of Renal Medicine, Birmingham Heartlands Hospital, Birmingham, UK
  11. 11The National Institute for Cardiovascular Outcomes Research, University College London, London, UK
  12. 12Interventional Radiology Unit, Gartnavel General Hospital, Glasgow, UK
  13. 13School of Physiology & Pharmacology, Bristol Cardiovascular Medical Sciences Building, University of Bristol, Bristol, UK
  14. 14International Centre for Circulatory Health, Imperial College, London, UK
  15. 15Wessex Regional Cardiac Unit, University Hospital Southampton, UK
  16. 16Institute of Cardiovascular Sciences, University College London, London, UK
  1. Correspondence to Dr Melvin D Lobo, Centre for Clinical Pharmacology, William Harvey Heart Centre, Barts and the London School of Medicine and Dentistry, Queen Mary University of London, Charterhouse Square, London EC1M 6BQ, UK; m.d.lobo{at}qmul.ac.uk

Abstract

Resistant hypertension continues to pose a major challenge to clinicians worldwide and has serious implications for patients who are at increased risk of cardiovascular morbidity and mortality with this diagnosis. Pharmacological therapy for resistant hypertension follows guidelines-based regimens although there is surprisingly scant evidence for beneficial outcomes using additional drug treatment after three antihypertensives have failed to achieve target blood pressure. Recently there has been considerable interest in the use of endoluminal renal denervation as an interventional technique to achieve renal nerve ablation and lower blood pressure. Although initial clinical trials of renal denervation in patients with resistant hypertension demonstrated encouraging office blood pressure reduction, a large randomised control trial (Symplicity HTN-3) with a sham-control limb, failed to meet its primary efficacy end point. The trial however was subject to a number of flaws which must be taken into consideration in interpreting the final results. Moreover a substantial body of evidence from non-randomised smaller trials does suggest that renal denervation may have an important role in the management of hypertension and other disease states characterised by overactivation of the sympathetic nervous system. The Joint UK Societies does not recommend the use of renal denervation for treatment of resistant hypertension in routine clinical practice but remains committed to supporting research activity in this field. A number of research strategies are identified and much that can be improved upon to ensure better design and conduct of future randomised studies.

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Scope of the consensus statement

Resistant hypertension (RHTN) is increasingly recognised as an important subset of uncontrolled hypertension that carries substantial additional risk for cardiovascular disease.1 ,2 Wide-ranging prevalence for RHTN has been reported which varies depending on which cohorts have been examined. However, it seems likely that the overall prevalence is around 8–10% of all patients with hypertension and that improved treatment of this group would lead to considerable reduction in cardiovascular morbidity and mortality making it a high priority hypertension subset.3 ,4

Renal denervation (RDN) therapy has recently become available as a treatment for proven RHTN, albeit with a clinical effectiveness evidence base limited to studies lacking blinded end points or sham controls and mostly with small numbers of patients.5–7 Following the announcement by Medtronic on 9 January 2014 that the Symplicity hypertension (HTN)-3 trial had failed to meet its primary efficacy end point, the Joint UK Societies released an interim statement recommending a temporary moratorium on RDN procedures undertaken as a standard of care in the UK while awaiting formal reporting and peer-reviewed publication of the study results.8 ,9 This updated statement was prepared following the recent publication of the Symplicity HTN-3 study—a prospective, single-blind, randomised, sham-controlled trial that took place in the USA.10 In this document we consider the RDN landscape that set the stage for the Symplicity HTN-3 study and thereafter review the study design and results. A number of limitations affecting the execution of the study are now apparent that provide important lessons for future studies of RDN. Importantly, given the conflicting evidence regarding the role of RDN, it is too early to use the Symplicity HTN-3 outcome as a rationale to abandon this novel therapeutic development. Here we also address critical issues that must be overcome if RDN is to progress as a therapy for RHTN or other forms of hypertension.

Symplicity HTN-3 background

The Symplicity HTN-3 study was conceived and designed as a regulatory study for US approval of RDN therapy as part of an ongoing multistage global clinical evaluation programme for radiofrequency (RF) RDN initiated by Medtronic.11 The study design allowed the investigators to address numerous concerns that had arisen in light of the initial studies reporting RDN as an efficacious and safe therapy for RHTN (see table 1).

Table 1

Criticisms of clinical renal denervation (RDN) data to date

Principal among these concerns were the fact that existing studies had failed to include blinded end points and, in particular, there was no mandated use of ambulatory blood pressure monitoring (ABPM) as a means to diagnose RHTN and to monitor response to the therapy. Furthermore, although Symplicity HTN-2 was a randomised controlled study, there was no sham control procedure which has been recorded as important in the proper evaluation of novel interventional procedures.29 ,30 Despite being a novel interventional procedure, there have been very few adverse reports pertaining to safety of the procedure, or long-term harmful sequelae although this may simply reflect numbers of procedures performed to date and lack of true long-term follow-up. Case reports of renal artery stenosis following denervation are a reminder of the importance of long-term scrutiny for renovascular disorder following RDN and careful surveillance of biochemical renal function.31 ,32

Other concerns over published RDN data sets included lack of specialist management of patients with RHTN (diagnosis and treatment, adequacy of per-protocol exclusion of secondary HTN), and that adherence to antihypertensive medication prior to enrolment and during the course of studies had not been assessed.33 ,34 Concomitantly, hypertension specialists in a number of European centres had also started to investigate the utility of RDN in patients with RHTN and have reported that the number of patients suitable for RDN (after specialist assessment and medication adjustment) would be very limited.12 ,35 ,36 Furthermore the high responder rates of 80% or more patients exhibiting office systolic blood pressure (SBP) reduction of >10 mm Hg in earlier trials were not replicable in a number of smaller studies which showed less striking blood pressure (BP) lowering and substantial heterogeneity of BP responses to RDN.37–39

Symplicity HTN-3 study design and results

The Symplicity HTN-3 study was a prospective, single-blind, randomised, sham-controlled trial in which patients with severe RHTN (office BP >160 mm Hg and 24-h mean SBP >135 mm Hg) were randomly assigned in a 2:1 ratio to undergo RDN or a sham procedure.11 Before randomisation, patients were intended to be receiving a stable antihypertensive regimen involving maximally tolerated doses of at least three drugs, including a diuretic. The primary efficacy end point was the change in office SBP at 6 months; a secondary efficacy end point was the change in mean 24-h ambulatory SBP. In total 535 subjects were randomised of whom 364 received RDN therapy and 171 had a sham procedure. The investigators ensured adequate blinding of study participants such that they were unaware whether they had received RDN therapy or sham control (renal angiogram) and BP assessors were blinded to the study group assignments. Although the primary safety end point was met, with a major adverse event rate of only 1.4% (set against an objective performance goal of <9.8%), the study failed to meet its primary and secondary efficacy end points with no statistically significant difference in either office or ABPM BP lowering between the RDN treatment and sham control arms (figure 1). Substantial variation in BP responses was noted in both study groups and subgroup analyses indicated that RDN therapy might work better in patients of non-African-American ethnicity, patients below the age of 65 years and those with preserved renal function (estimated glomerular filtration rate >60 mL/min).10

Figure 1

Symplicity HTN-3 results of primary and secondary efficacy end points.

Symplicity HTN-3: study limitations and lessons for future trials of RDN

The Symplicity HTN-3 study improved upon Symplicity HTN-1 and HTN-2 in having a blinded secondary end point (ABPM) and a sham control group. However, following publication of the results and presentation in international meetings, a number of findings have come to light that indicate that there are important lessons to be learnt about the optimal design and execution of such studies.

Medications stability

The study design mandated each enrolled patient was on a maximum tolerated dose or maximum Food and Drug Administration (FDA)-approved dose of at least three antihypertensive agents from different classes, for at least 2 weeks prior to enrolment. Although there was an emphasis on maintaining a constant therapeutic regimen throughout the study, as many as 20% of patients were not on stable medications within 6 weeks of inclusion.40 Given that attainment of full effect of diuretics (including aldosterone antagonists) is known to take up to 8 weeks,41 it is quite possible that some of the BP changes in both study limbs were due to late effects of the enrolment medication regimen.

There were also substantial differences in use of aldosterone antagonists (22.5/28.7%) and vasodilators (36.8/45%) between the RDN/sham limbs at baseline, respectively, and a preponderance of African-Americans, who are more likely to respond to these drug classes, in the sham group (29.2% sham vs 24.8% RDN). Indeed African-American patients demonstrated a striking SBP reduction of 17.8 mm Hg in the sham arm versus 15.5 mm Hg in the RDN limb.

Approximately 40% of patients in both arms required medications changes during the study which is unusual.40 The exact reasons for and the disposition of the medication changes are yet to be clarified. It is noteworthy that there were eight points of investigator/subject contact during the study with close scrutiny of medications and BP at every point. It is possible that medication compliance was artificially enhanced in this study (the Hawthorne effect). Of note, although patients were asked to maintain a medication diary, adherence to antihypertensive medication was not formally tested by directly observed therapy or by urine antihypertensive drug assay in this study. It is also unfortunate that long-term follow-up of the sham control population is already confounded by high cross-over to active therapy with RDN which will negatively impact on the opportunity to determine if the sham treatment alone had long-term implications for BP control.

RDN procedures

Attention has already focused on the large number of sites in Symplicity HTN-3 with 111 interventionists who performed at least one RDN procedure (34% did only a single procedure) and with only 26 operators undertaking more than five procedures.42 Although procedures were proctored (mostly by non-clinical staff), this does not imply that optimal denervation was achieved.

In fact in this study the mean total number of ablation attempts was 11.2±2.8 per patient with a mean of 9.2±2.0 per protocol 120 s ablations. In the Global Symplicity Registry (GSR), ambulatory SBP reduced by 10.3 mm Hg (in patients with office BP >160 mm Hg and ambulatory BP >135 mm Hg) compared with a reduction in ambulatory SBP of only 6.8 mm Hg in the RDN group and 4.8 mm Hg in the sham group in Symplicity HTN-3.43 In the GSR the mean number of bilateral ablations was 13.5±4.1, and the mean number of 120 s bilateral ablations was 11.3±3.4. In HTN-3 it was shown that with an increasing number of RF ablations there was a greater reduction in BP; in 40 patients who underwent RDN who had more than 13 total ablation attempts there was a 10.3 mm Hg reduction in ambulatory SBP, matching the effect size in the GSR.40

In Symplicity HTN-3 only a small proportion of patients had per-protocol RF ablation in all four quadrants of both renal arteries.40 Disappointingly, but not surprisingly, matched cohort analysis has indicated that delivery of ablations in all four quadrants of the renal artery was also associated consistently with the greatest reductions in office, home and ambulatory SBP (−24.3, −9.0 and −10.3 mm Hg, respectively) but this only applied in 19 patients out of 364 patients undergoing RDN.40

Evidence that suggests RDN may be beneficial for RHTN

Data from numerous animal models have previously suggested an important role for the renal sympathetic nervous system (SNS) in the initiation and perpetuation of hypertension.44 In addition, a number of human studies had demonstrated the importance of renal nerve signalling in hypertension prior to the publication of the Symplicity HTN-1 and HTN-2 studies. These data have been reviewed extensively elsewhere.45 Data from a number of smaller studies have indicated efficacy for RDN in BP lowering and improving other aspects of cardiovascular function and merit consideration as follows.

Improvement in ABPM parameters

While Symplicity HTN-1 and HTN-2 provided data for efficacy and safety of RDN, the lack of ABPM in either inclusion criteria or monitoring of BP in response to RDN has been criticised. However, non-randomised data supporting sizeable effects of RDN on office and ABPM parameters have now been published in a study of 346 patients with true RHTN (n=303) and pseudoresistant HTN (n=43).14 Early and sustained significant reductions in office SBP and diastolic blood pressure (DBP) were shown at 3 months, 6 months and 12 months follow-up (office SBP: −21.5/−23.7/−27.3 mm Hg, office DBP: −8.9/−9.5/−11.7 mm Hg), respectively. There was a significant reduction with RDN in 24 h SBP (−10.1/−10.2/−11.7 mm Hg,) and diastolic blood pressure (DBP) (−4.8/−4.9/−7.4 mm Hg) at 3 months, 6 months and 12 months, respectively, as well as reduction in BP variability in those patients with true RHTN. In patients with pseudoresistant hypertension there was no effect on ABPM post denervation arguing strongly against a sham effect. The GSR, presented at the American College of Cardiology meeting (March 2014), demonstrated a reduction of 10.3 mm Hg in mean 24 h SBP in 52 patients with treatment-RHTN taking three or more antihypertensives at maximally tolerated doses with an office BP >160 mm Hg.43

RDN enables regression of LV hypertrophy

Reduction in LV hypertrophy and improvement in cardiac function has been demonstrated in patients with RHTN following RDN.46 Intriguingly it has been proposed that improvement in cardiac function and LV hypertrophy regression was independent of the magnitude of BP reduction, suggesting suppression of neurohumoural mechanisms. It must be noted however that this was a prospective, non-randomised, open-label unipolar RF denervation single-centre study in a small number of patients without sham control. More recently catheter based RDN was demonstrated to significantly reduce BP and LV mass and improve EF in patients with RHTN using cardiac MRI.47 Once again this prospective multicentre study of only 72 patients was non-randomised and with open-label use of RDN. Importantly, however, the magnitude of LV mass reduction seen was less than that noted in echocardiographic studies of RDN but still comparable with that seen in patients with hypertension treated with pharmacotherapy.48 Although a profound placebo effect or greater compliance with medication might have influenced results, to some extent the reduction in LV mass occurred independently of BP reduction which raises the tantalising prospect that downregulation of central cardiac (but not vasomotor) sympathetic outflow resulting from RDN may have a direct role to play in modulating hypertensive heart disease. The potential of RDN as a treatment for heart failure warrants further study.

Other possible cardiovascular benefits of RDN

RDN reduces heart rate in humans and may have beneficial effects in cardiac rhythm disturbance including reduction in burden of atrial fibrillation and possibly ventricular arrhythmias as well.49 ,50 RDN was shown to reduce arterial stiffness and central haemodynamics which are important prognostic markers and this too merits further investigation.51 In two small studies, investigators have shown that RDN improves health-related quality of life and that this improvement was not necessarily related to the magnitude of BP reduction.52 ,53

Current state of RDN therapy in the UK

When RDN therapy first became available as a treatment for RHTN, there was rapid uptake of the procedure in a number of European Union territories where a Conformité Européene mark had been established for various competing technologies and this led to over 10 000 RDN procedures being undertaken worldwide with regrettably little in the way of data capture with the exception of several investigators who have been pioneers in the field. In contrast, UK uptake has been much slower with only a handful of centres offering the procedure with responder rates that have been markedly heterogeneous and less encouraging on the whole.22 ,54 ,55

At one point in 2013 there were more than 60 companies with technologies in development for RDN including first and second generation RF ablation catheters, ultrasound catheters, radiotherapy catheters, cryotherapy and chemical ablation technologies.18 Following the Symplicity HTN-3 announcement a number of companies have announced their withdrawal from the field of device therapy for hypertension including such large entities as Covidien. However, several of the major devices manufactures including Boston Scientific, Medtronic and St Jude Medical, having suspended clinical trial activity within pre-existing programmes, have announced their intention to commit to the field of renal sympathectomy. They are using the outputs from Symplicity HTN-3 as an opportunity to improve design of their future clinical trials.

The Joint UK Societies updated perspective

After reviewing the evidence from the Symplicity HTN-1 and HTN-2 studies, the Joint UK Societies produced guidance for the use of RDN in the UK in 2011 which was summarised in an electronically published summary consensus statement.56 The National Institute for Health and Care Excellence subsequently produced interim guidance for RDN that was very much in line with our initial guidance.57 In order to protect patients from overenthusiastic and/or inappropriate application of the procedure, it was mandated that patients only be treated with RDN in the context of multidisciplinary assessment in centres of excellence with Hypertension Specialists leading on case management. The procedure, which would be costly for the UK's National Health Service, was to be funded by a novel process of ‘Commissioning Through Evaluation’ designed to ensure capture of data from all procedures in a national registry, which would serve as a clinical and academic resource.58 Subsequently other expert group statements have also been published from the European Society of Hypertension, European Society of Cardiology, Cardiovascular and Interventional Radiology Society of Europe and an International expert Consensus Statement all supporting the use of RDN therapy as a treatment option for RHTN where routine measures to control BP have failed.59–62

Following close upon the heels of the Medtronic Symplicity HTN-3 press announcement, the Joint UK Societies produced an interim statement calling for a temporary moratorium on UK use of RDN therapy in anticipation of the formal publication and presentation of the data.9 Even allowing for debate over the interpretation of the outcomes of the Symplicity HTN-3 study, there is still a lack of evidence to support the routine use of RDN as a standard of care in RHTN. Hence, we recommend the current moratorium on use of this procedure in the UK remains in place until such time as there is Level 1 evidence in favour of use of RDN. This view is in line with the published evidence and is supported by a recent meta-analysis suggesting that more large-scale randomised controlled trials in RDN are needed before this treatment should be considered in routine clinical practice.63

Importantly, the Joint UK Societies recognise that a substantial amount of (Level II or lesser) evidence does suggest clinical utility for RDN therapy in some patients and thus we feel that the therapy should not be abandoned in light of the Symplicity HTN-3 study result. Indeed, this study has continued to disseminate outputs that are proving to be helpful in our learning of how better to manage future studies of RDN. It will be essential for device manufacturers, multidisciplinary clinicians and researchers to collaborate closely to effectively define the path for future studies. Key learning points from the Symplicity HTN-3 study are summarised in table 2.

Table 2

Key lessons from Symplicity HTN-3

The UK remains committed to leading, supporting and participating in well-designed randomised controlled studies to assess the future role of RDN in RHTN. As such the moratorium does not apply to clinical trials of RDN therapy. It is important that alternative energy modalities, such as ultrasound and chemical ablation technologies should be investigated along with second and third generation RF catheters in appropriately designed clinical studies with blinded end points to include ABPM. In RHTN it is vital that careful evaluation of drug adherence is included as a prerequisite to study entry unless severe medication intolerance has been diagnosed. Recently mass spectrometry drug measurement in urine has demonstrated that many patients are not adherent with their therapy.64 The application of similar measures in future studies will robustly confirm resistance and allow us to detect non-concordance. It is also important that patients should not be enrolled in studies within 8 weeks of the last change in treatment.

Critical areas to address to determine the role of RDN as a therapy for RHTN

The key areas that future research in RDN must address are summarised in table 1. It is remarkable that to date there is no agreement on the precise anatomy of the human sympathetic nerves and in particular the variation in their trajectories relative to the renal arteries. In a small study of nine renal arteries harvested from five human autopsies, it was reported that the majority of renal nerves lie within 2 mm distance from the lumen of the renal artery.65 However, the fixation methodology used has been criticised and other workers have suggested that in humans, renal nerve distribution varies between the proximal-distal segments of the renal artery and that the 50th and 75th centiles of distance of nerves in the proximal segment are 2.84 and 4.67 mm, respectively.66 Clearly, precise localisation of human renal nerves has crucial implications for the application of RDN and it is important to bear in mind that different ablation technologies (eg, RF energy, ultrasound energy, chemical ablation) offer varying depths of renal sympathectomy and it remains to be proven which is most effective for human use.

Since renal nerves spiral around the artery, it is also clear that denervation in all four quadrants of the renal artery is necessary. This may be achieved through the use of multielectrode RF ablation catheters and alternative means of sympathectomy including ultrasound and chemical ablation techniques. Ultrasound energy may offer benefit by avoiding endothelial damage and deeper penetration of heating energy than RF. Chemical ablation techniques with alcohol or guanethidine also offer potential advantage in obviating endothelial damage although it remains unclear whether or not dissemination of neurotoxin beyond the periadventitial layer could be an undesired effect of such therapy.18 Determining which energy modality and ablation therapy is best to achieve near complete renal nerve ablation in the absence of damage to the renal artery lumen (and off-target effects) remains a priority.

At present there is no marker of procedural success to inform operators that RDN therapy has been successfully delivered although in a number of studies it has been demonstrated that the higher the starting SBP, the greater the response to RDN. Preliminary data from humans indicate there could be a role for high frequency electrical field stimulation of the renal arteries.24 In a canine model, intralumenal renal artery electrical stimulation (to activate renal nerves) was shown to increase BP, serum catecholamines and heart rate variability, presumably through activation of renal afferent reflexes; these effects were attenuated following RDN.25 Currently there are no established biomarkers of renal nerve injury (a neural ‘troponin’ would be ideal) and early plasma markers of renal injury have not translated as trustworthy markers. Thus, interventionists remain uninformed as to whether or not the RDN procedure they have undertaken has achieved its intended purpose.

Ideally treatment with RDN would be limited to those patients most likely to respond to the therapy. If a response rate is defined as a reduction in office SBP of 10 mm Hg or more, a number of non-randomised and non-blinded studies have indicated responder rates in excess of 80%. However real world experience of RDN suggests true responder rates are much more variable22 ,39 ,54 ,55 and as such it might be ideal to phenotype patients with hypertension to better predict responders/non-responders. Biochemical and ethnic phenotyping is already in place in the National Institute for Health and Care Excellence/British Hypertension Society guideline for antihypertensive pharmacotherapy where patients with low renin status (black ethnicity) are offered calcium channel blockers as first-line therapy and those with high renin status (Caucasian ethnicity) receive ACE/angiotensin receptor blocker drugs instead.67 Given the complexity of SNS signalling and how this related to changes in vasomotor tone, and the lack of easy applicable tests for large-scale determination of renal sympathetic overactivation, it seems unlikely that hypertension phenotyping for SNS upregulation will evolve into mainstream clinical practice.

One approach that merits further study is the use of non-invasive techniques to assess baroreflex sensitivity (BRS) as impaired BRS was shown to be strongly predictive of response to RDN in patients with RHTN (although it did not predict the magnitude of BP reduction).23 RDN was found to consistently improve BRS in all patients studied regardless of heterogeneous effects on BP.22 Multivariate logistic regression analysis showed lower levels of BRS to be the strongest predictor of response to RDN and independent of all other variables.23 Another small study has demonstrated a novel potential role for elevated plasma levels of angiogenic markers such as soluble fms-like tyrosine kinase-1, intercellular cell adhesion molecule-1 and vascular cell adhesion molecule-1 as predictors of response to RDN.68

Conclusion

Despite the negative results from Symplicity HTN-3, it is too early to decide that RDN therapy is a failed treatment strategy for RHTN. Sufficient encouraging data for RDN as a means to treat hypertension have emerged in a number of animal models of hypertension as well as some human studies to attest to its potential as an effective treatment for at least a subsection of patients. Furthermore, studies have indicated that RDN may attenuate hypertensive heart disease, decrease arrhythmia burden and reduce arterial stiffness in addition to lowering BP. Heterogeneity in BP responses do suggest that RDN is not a treatment for all-comers with RHTN and that careful patient selection will need to be augmented by better understanding of who might best respond.

It is now the time to focus on improved study design and meticulous execution of clinical trials with careful proctoring of interventionalists who are unfamiliar with the procedure as there is undoubtedly a learning curve with all novel procedures no matter how simple they may seem from the outset. Although there is unmet need for improved treatment strategies for patients with RHTN, it is also quite possible that chronic RHTN, with all the attendant circulatory maladaptation and arterial stiffening that ensues, may not represent the best target group of patients who would derive most benefit from RDN. It remains to be proven whether or not patients with milder forms of hypertension of shorter duration could be the most appropriate population for this therapy—once again high quality clinical studies are mandated particularly as the therapy becomes less expensive in the future. Until we have better evidence of the clinical efficacy in well conducted trials the Joint UK Societies recommend continuing the moratorium on RDN in routine UK healthcare. The UK is ready to contribute to further study the place of this therapy in the management of RHTN. With the current uncertainties, it would not be reasonable to expect commissioners to meet the costs of treatment in newly designed postmarketing studies. Industry will need to meet the costs of industry-sponsored studies although we hope that commissioners will support the clinical costs of National Institute for Health Research-funded studies.

References

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Footnotes

  • Contributors MDL conceived, designed and drafted this article, has undertaken multiple revisions of the text and takes full responsibility for this article. All other authors have reviewed and contributed to revisions of the manuscript.

  • Competing interests MDL is on the speaker bureau for St Jude Medical and has participated in advisory boards for St Jude Medical.

  • Provenance and peer review Not commissioned; internally peer reviewed.

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