Endocrine and haemodynamic changes in resistant hypertension, and blood pressure responses to spironolactone or amiloride: the PATHWAY-2 mechanisms substudies

Bryan Williams, Thomas M MacDonald, Steve V Morant, David J Webb, Peter Sever, Gordon T McInnes, Ian Ford, J Kennedy Cruickshank, Mark J Caulfield, Sandosh Padmanabhan, Isla S Mackenzie, Jackie Salsbury, Morris J Brown, British Hypertension Society programme of Prevention And Treatment of Hypertension With Algorithm based Therapy (PATHWAY) Study Group, K Balakrishnan, T Burton, J Cannon, D Collier, C Coughlan, R D'Souza, E Enobakhare, E Findlay, C Gardiner-Hill, P Gupta, J Helmy, C Helmy, L Hobbs, R Hobbs, S Hood, R Iles, S Kean, S Kwok, P Lacy, I MacIntyre, J Mackay, N Markandu, U Martin, L McCallum, G McCann, A McGinnis, V Melville, S Muir, K S Myint, S Nazir, J Palmer, R Papworth, K Rutkowski, M Saxena, A Schumann, H Soran, A Stanley, S Thom, A Webb, C White, R Wilson, A Zak, Bryan Williams, Thomas M MacDonald, Steve V Morant, David J Webb, Peter Sever, Gordon T McInnes, Ian Ford, J Kennedy Cruickshank, Mark J Caulfield, Sandosh Padmanabhan, Isla S Mackenzie, Jackie Salsbury, Morris J Brown, British Hypertension Society programme of Prevention And Treatment of Hypertension With Algorithm based Therapy (PATHWAY) Study Group, K Balakrishnan, T Burton, J Cannon, D Collier, C Coughlan, R D'Souza, E Enobakhare, E Findlay, C Gardiner-Hill, P Gupta, J Helmy, C Helmy, L Hobbs, R Hobbs, S Hood, R Iles, S Kean, S Kwok, P Lacy, I MacIntyre, J Mackay, N Markandu, U Martin, L McCallum, G McCann, A McGinnis, V Melville, S Muir, K S Myint, S Nazir, J Palmer, R Papworth, K Rutkowski, M Saxena, A Schumann, H Soran, A Stanley, S Thom, A Webb, C White, R Wilson, A Zak

Abstract

Background: In the PATHWAY-2 study of resistant hypertension, spironolactone reduced blood pressure substantially more than conventional antihypertensive drugs. We did three substudies to assess the mechanisms underlying this superiority and the pathogenesis of resistant hypertension.

Methods: PATHWAY-2 was a randomised, double-blind crossover trial done at 14 UK primary and secondary care sites in 314 patients with resistant hypertension. Patients were given 12 weeks of once daily treatment with each of placebo, spironolactone 25-50 mg, bisoprolol 5-10 mg, and doxazosin 4-8 mg and the change in home systolic blood pressure was assessed as the primary outcome. In our three substudies, we assessed plasma aldosterone, renin, and aldosterone-to-renin ratio (ARR) as predictors of home systolic blood pressure, and estimated prevalence of primary aldosteronism (substudy 1); assessed the effects of each drug in terms of thoracic fluid index, cardiac index, stroke index, and systemic vascular resistance at seven sites with haemodynamic monitoring facilities (substudy 2); and assessed the effect of amiloride 10-20 mg once daily on clinic systolic blood pressure during an optional 6-12 week open-label runout phase (substudy 3). The PATHWAY-2 trial is registered with EudraCT, number 2008-007149-30, and ClinicalTrials.gov, number NCT02369081.

Findings: Of the 314 patients in PATHWAY-2, 269 participated in one or more of the three substudies: 126 in substudy 1, 226 in substudy 2, and 146 in substudy 3. Home systolic blood pressure reduction by spironolactone was predicted by ARR (r2=0·13, p<0·0001) and plasma renin (r2=0·11, p=0·00024). 42 patients had low renin concentrations (predefined as the lowest tertile of plasma renin), of which 31 had a plasma aldosterone concentration greater than the mean value for all 126 patients (250 pmol/L). Thus, 31 (25% [95% CI 17-33]) of 126 patients were deemed to have inappropriately high aldosterone concentrations. Thoracic fluid content was reduced by 6·8% from baseline (95% CI 4·0 to 8·8; p<0·0001) with spironolactone, but not other treatments. Amiloride (10 mg once daily) reduced clinic systolic blood pressure by 20·4 mm Hg (95% CI 18·3-22·5), compared with a reduction of 18·3 mm Hg (16·2-20·5) with spironolactone (25 mg once daily). No serious adverse events were recorded, and adverse symptoms were not systematically recorded after the end of the double-blind treatment. Mean plasma potassium concentrations increased from 4·02 mmol/L (95% CI 3·95-4·08) on placebo to 4·50 (4·44-4·57) on amiloride (p<0·0001).

Interpretation: Our results suggest that resistant hypertension is commonly a salt-retaining state, most likely due to inappropriate aldosterone secretion. Mineralocorticoid receptor blockade by spironolactone overcomes the salt retention and resistance of hypertension to treatment. Amiloride seems to be as effective an antihypertensive as spironolactone, offering a substitute treatment for resistant hypertension.

Funding: British Heart Foundation and UK National Institute for Health Research.

Copyright © 2018 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY 4.0 license. Published by Elsevier Ltd.. All rights reserved.

Figures

Figure 1
Figure 1
PATHWAY 2 study design Stages in the crossover trial at which measurements for the three mechanistic substudies were taken. Green shows substudy 1, blue shows substudy 2, and pink shows substudy 3. During the 12-week drug cycles, the lower dose was given for the first 6 weeks, then the higher dose was given for the second 6 weeks. No washout period was used between cycles. The figure shows one of the 24 possible passages through the drug cycles, the order of which was randomly assigned within blocks of 24 patients. A+C+D=an angiotensin-converting enzyme inhibitor or angiotensin receptor blocker, a calcium channel blocker, and a diuretic.
Figure 2
Figure 2
Participant numbers and measurements in the PATHWAY-2 mechanisms substudies
Figure 3
Figure 3
Correlations of plasma aldosterone, renin, and ARR, with blood pressure response to spironolactone averaged (mean) across the 6-week and 12-week visits of each treatment cycle (A) Relation between baseline plasma renin, aldosterone, and the ARR and the home systolic blood pressure response to spironolactone. (B) Best-fit relation between plasma aldosterone and renin concentrations at baseline. Regression equations for change in systolic blood pressure (y): y=(−25·20)+6·86 × (log10renin), r2=0·116 (proportion of variance accounted for by the model); y=8·92–9·85 × (log10aldosterone), r2=0·034; and y=(−8·87)–6·87 × (log10ARR), r2=0·138. Regression equation for aldosterone vs renin: log10aldosterone=2·60–0·279 × (log10renin) + 0·081 × (log10renin)2, r2=0·043. ARR=aldosterone-to-renin ratio.
Figure 4
Figure 4
Change in haemodynamic parameters from baseline after 12 weeks treatment with spironolactone, doxazosin, bisoprolol, and placebo Stroke index, cardiac index, vascular resistance index, and thoracic fluid index were measured at baseline and the end of each double-blind treatment cycle. Least squares means adjusted for gender, height, weight, smoking history, baseline systolic blood pressure, and the baseline measurement of the outcome, from a mixed model allowing for correlations between repeat measurements in each patient. Coloured bars show least squares mean values and black bars show 95% CIs.
Figure 5
Figure 5
Effect of placebo, amiloride, spironolactone, doxazosin, and bisoprolol on clinic blood pressure after 6 weeks of treatment Both amiloride and spironolactone reduced systolic and diastolic blood pressure (unadjusted means) versus placebo (p

Figure 6

Correlation between change in systolic…

Figure 6

Correlation between change in systolic blood pressure in patients treated with amiloride and…

Figure 6
Correlation between change in systolic blood pressure in patients treated with amiloride and in those treated with spironolactone after 6 weeks of treatment Dotted lines show corresponding points on y axis (for amiloride) and x axis (for spironolactone) for mean responses (red) and zero responses (blue).
Figure 6
Figure 6
Correlation between change in systolic blood pressure in patients treated with amiloride and in those treated with spironolactone after 6 weeks of treatment Dotted lines show corresponding points on y axis (for amiloride) and x axis (for spironolactone) for mean responses (red) and zero responses (blue).

References

    1. Myat A, Redwood SR, Qureshi AC, Spertus JA, Williams B. Resistant hypertension. BMJ. 2012;345:e7473.
    1. Achelrod D, Wenzel U, Frey S. Systematic review and meta-analysis of the prevalence of resistant hypertension in treated hypertensive populations. Am J Hypertens. 2015;28:355–361.
    1. Williams B, MacDonald TM, Morant S. Spironolactone versus placebo, bisoprolol, and doxazosin to determine the optimal treatment for drug-resistant hypertension (PATHWAY-2): a randomised, double blind, crossover trial. Lancet. 2015;386:2059–2068.
    1. Dickerson JEC, Hingorani AD, Ashby MJ, Palmer CR, Brown MJ. Optimisation of antihypertensive treatment by crossover rotation of four major classes. Lancet. 1999;353:2008–2013.
    1. Dahal K, Kunwar S, Rijal J. The effects of aldosterone antagonists in patients with resistant hypertension: a meta-analysis of randomized and nonrandomized studies. Am J Hypertens. 2015;28:1376–1385.
    1. Williams B, MacDonald TM, Caulfield M. Prevention and treatment of hypertension with algorithm-based therapy (PATHWAY) number 2: protocol for a randomised crossover trial to determine optimal treatment for drug-resistant hypertension. BMJ Open. 2015;5:e008951.
    1. Brown MJ, Williams B, Morant SV. Effect of amiloride, or amiloride plus hydrochlorothiazide, versus hydrochlorothiazide on glucose tolerance and blood pressure (PATHWAY-3): a parallel-group, double-blind randomised phase 4 trial. Lancet Diabetes Endocrinol. 2016;4:136–147.
    1. Tomaszewski M, White C, Patel P. High rates of non-adherence to antihypertensive treatment revealed by high-performance liquid chromatography-tandem mass spectrometry (HP LC-MS/MS) urine analysis. Heart. 2014;100:855–861.
    1. Fortunato A, Prontera C, Masotti S. State of the art of aldosterone immunoassays. A multicenter collaborative study on the behalf of the Cardiovascular Biomarkers Study Group of the Italian Section of European Society of Ligand Assay (ELAS) and Società Italiana di Biochimica Clinica (SIBIOC) Clin Chim Acta. 2015;444:106–112.
    1. Taler SJ, Textor SC, Augustine JE. Resistant hypertension: comparing hemodynamic management to specialist care. Hypertension. 2002;39:982–988.
    1. Greenberg BH, Hermann DD, Pranulis MF, Lazio L, Cloutier D. Reproducibility of impedance cardiography hemodynamic measures in clinically stable heart failure patients. Congest Heart Fail. 2000;6:74–80.
    1. Song Y, Yang S, He W. Confirmatory tests for the diagnosis of primary aldosteronism: a prospective diagnostic accuracy study. Hypertension. 2018;71:118–124.
    1. Willenberg HS, Kolentini C, Quinkler M. The serum sodium to urinary sodium to (serum potassium)2 to urinary potassium (SUSPPUP) ratio in patients with primary aldosteronism. Eur J Clin Invest. 2009;39:43–50.
    1. Douma S, Petidis K, Doumas M. Prevalence of primary hyperaldosteronism in resistant hypertension: a retrospective observational study. Lancet. 2008;371:1921–1926.
    1. Brown MJ. Renin: friend or foe? Heart. 2007;93:1026–1033.
    1. MacDonald TM, Williams B, Webb DJ. Combination therapy is superior to sequential monotherapy for the initial treatment of hypertension: a double-blind randomized controlled trial. J Am Heart Assoc. 2017;6:e006986.
    1. Klenow S, Thamm M, Mensink GBM. Sodium intake in Germany estimated from sodium excretion measured in spot urine samples. BMC Nutr. 2016;2:36.
    1. Williams GH, Tuck ML, Rose LI, Dluhy RG, Underwood RH. Studies of the control of plasma aldosterone concentration in normal man. 3. Response to sodium chloride infusion. J Clin Invest. 1972;51:2645–2652.
    1. Brunner HR, Laragh JH, Baer L. Essential hypertension: renin and aldosterone, heart attack and stroke. N Engl J Med. 1972;286:441–449.
    1. Stewart PM, Wallace AM, Atherden SM, Shearing CH, Edwards CR. Mineralocorticoid activity of carbenoxolone: contrasting effects of carbenoxolone and liquorice on 11β-hydroxysteroid dehydrogenase activity in man. Clin Sci. 1990;78:49–54.
    1. Funder JW, Carey RM, Mantero F. The management of primary aldosteronism: case detection, diagnosis, and treatment: an Endocrine Society clinical practice guideline. J Clin Endocrinol Metab. 2016;101:1889–1916.
    1. Brown MJ, Sudano I. Problems and solutions in the management of resistant hypertension. European Society of Cardiology Webinar. April 4, 2014. (accessed March 18, 2018).
    1. Monticone S, Burrello J, Tizzani D. Prevalence and clinical manifestations of primary aldosteronism encountered in primary care practice. J Am Coll Cardiol. 2017;69:1811–1820.
    1. Rossi GP, Bernini G, Caliumi C. A prospective study of the prevalence of primary aldosteronism in 1,125 hypertensive patients. J Am Coll Cardiol. 2006;48:2293–2300.
    1. Azizan EA, Poulsen H, Tuluc P. Somatic mutations in ATP1A1 and CACNA1D underlie a common subtype of adrenal hypertension. Nat Genet. 2013;45:1055–1060.
    1. Fernandes-Rosa FL, Williams TA. Genetic spectrum and clinical correlates of somatic mutations in aldosterone-producing adenoma. Hypertension. 2014;64:354–361.
    1. Akerstrom T, Willenberg HS, Cupisti K. Novel somatic mutations and distinct molecular signature in aldosterone-producing adenomas. Endocr Relat Cancer. 2015;22:735–744.
    1. Monticone S, Castellano I, Versace K. Immunohistochemical, genetic and clinical characterization of sporadic aldosterone-producing adenomas. Mol Cell Endocrinol. 2015;411:146–154.
    1. Nishimoto K, Tomlins SA, Kuick R. Aldosterone-stimulating somatic gene mutations are common in normal adrenal glands. Proc Natl Acad Sci USA. 2015;112:E4591–E4599.
    1. Bogman K, Schwab D, Delporte ML. Preclinical and early clinical profile of a highly selective and potent oral inhibitor of aldosterone synthase (CYP11B2) Hypertension. 2017;69:189–196.
    1. Markou A, Sertedaki A, Kaltsas G. Stress-induced aldosterone hyper-secretion in a substantial subset of patients with essential hypertension. J Clin Endocrinol Metab. 2015;100:2857–2864.
    1. Steichen O, Blanchard A, Plouin PF. Assessment of serum sodium to urinary sodium divided by (serum potassium)2 to urinary potassium as a screening tool for primary aldosteronism. Eur J Clin Invest. 2011;41:189–194.
    1. Mackenzie IS, Morant SV, Wei L, Thompson AM, MacDonald TM. Spironolactone use and risk of incident cancers: a retrospective, matched cohort study. Br J Clin Pharmacol. 2017;83:653–663.
    1. Chuang YW, Yu MC, Huang ST. Spironolactone and the risk of urinary tract cancer in patients with hypertension: a nationwide population-based retrospective case-control study. J Hypertens. 2017;35:170–177.
    1. Liu SY, Chu CM, Kong AP. Radiofrequency ablation compared with laparoscopic adrenalectomy for aldosterone-producing adenoma. Br J Surg. 2016;103:1476–1486.

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