New drug therapies for hypertension.
Summary
New drug therapies for hypertension The Lancet 2026 Therapeutics New drug therapies for hypertension Michel Azizi, Katherine R Tuttle, Jenifer M Brown, Daniel L Piskorz, Kazuomi Kario, Bryan Williams Despite the availability of eective antihypertensive therapies, global blood pressure control rates remain unacceptably Published Online low. Contributing factors, such as low treatment adherence, therapeutic inertia, and rising multimorbidity, underscore February 10, 2026 the need for innovative a
Content
# New drug therapies for hypertension
*The Lancet 2026*
Therapeutics
New drug therapies for hypertension
Michel Azizi, Katherine R Tuttle, Jenifer M Brown, Daniel L Piskorz, Kazuomi Kario, Bryan Williams
Despite the availability of eective antihypertensive therapies, global blood pressure control rates remain unacceptably Published Online
low. Contributing factors, such as low treatment adherence, therapeutic inertia, and rising multimorbidity, underscore February 10, 2026
the need for innovative approaches to improve hypertension care. New antihypertensive drug therapies that act on https://doi.org/10.1016/
S0140-6736(25)02064-1
physiological pathways beyond those targeted by conventional drug classes are emerging. These therapies include
Hypertension Department,
small interfering RNA agents that inhibit angiotensinogen synthesis as a novel approach to inhibit the renin–
INSERM CIC1418, Hôpital
angiotensin system, and new strategies to more selectively modulate aldosterone, such as aldosterone synthase Européen Georges Pompidou
inhibitors and non-steroidal mineralocorticoid receptor antagonists. There is also growing interest in therapies to APHP, Université Paris Cité,
enhance the action of the natriuretic peptide system. Although these innovations present valuable therapeutic Paris, France (Prof M Azizi MD);
Division of Nephrology and
opportunities, their benefits must be carefully balanced against considerations of safety, cost, clinical outcomes, and
Kidney Research Institute,
equitable access—all of which are crucial to reducing the residual burden of cardiovascular and chronic kidney University of Washington
disease. School of Medicine, Seattle,
WA, USA (Prof K Tuttle MD);
Providence Medical Research
Introduction inhibiting the translation of the angiotensinogen mRNA,
Center, Providence Inland
Arterial hypertension aects an estimated 25–30% of resulting in almost complete suppression of hepatic Northwest Health, Spokane,
adults worldwide1 and remains the leading contributor to angiotensinogen production. Angiotensinogen is the WA, USA (Prof K Tuttle);
Division of Cardiovascular
cardiovascular morbidity and mortality.2 However,
Medicine, Department of
despite the widespread availability of eective, low-cost
Medicine, Brigham and
antihypertensive drugs, including single-pill comb- Search strategy and selection criteria Women’s Hospital, Harvard
inations,3–6 global control rates of arterial hypertension Medical School, Boston, MA,
We searched MEDLINE, Current Contents, PubMed, and
USA (J M Brown MD); Instituto
remain unacceptably low.1 Multiple factors underlie this
references from relevant articles using the search terms de Cardiología, Sanatorio
treatment gap, including low adherence to recommended
“antihypertensive drug(s)”, “blood pressure-lowering Británico, Rosario, Santa Fe,
lifestyle changes and medications, therapeutic inertia, drug(s)”, “randomised controlled trials”, “meta-analysis”, Argentina (D L Piskorz MD);
target organ damage, rising obesity and multimorbidity, Division of Cardiovascular
“systematic review”, “zilebesiran”, “IONIS-AGT-LRx”,
Medicine, Department of
population ageing, and socioeconomic inequalities.7,8
“osilodrostat”, “baxdrostat”, “lorundrostat”, “dexfadrostat Medicine, Jichi Medical
The complex and multifactorial pathophysiology of phosphate”, “BI 690517 OR vicadrostat”, “esaxerenone”, University School of Medicine,
hypertension9 means that existing pharmacological “ocedurenone”, “finerenone”, “aprocitentan”, “M-atrial Tochigi, Japan (Prof K Kario MD);
classes, even in combination, fail to address all contri- University College London
natriuretic peptide”, “XXB750”, “REGN5381”, “sacubitril/
Institute of Cardiovascular
buting mechanisms, particularly in patients with
valsartan”, “soluble guanylate cyclase stimulators”, and Science and National Institute
resistant hypertension, chronic kidney disease, or “firibastat”. Abstracts and reports from meetings were for Health Research UCL
diabetes.7 These challenges have led to renewed eorts to included only when they related directly to previously Hospitals Biomedical Research
develop drugs targeting novel pathways to improve blood Centre, London, UK
published work. Only articles published in English between
(Prof B Williams MD)
pressure control in individuals with hypertension. In the
Jan 1, 2015, and Sept 1, 2025, were included, but we did not
Correspondence to:
past 10 years, novel therapeutic approaches have entered
exclude commonly referenced older publications. We Prof Michel Azizi, Hypertension
clinical develop ment, targeting well characterised
excluded the endothelin receptor antagonists sparsentan, Department, INSERM CIC1418,
pathways such as the renin–angiotensin–aldosterone avosentan, atrasentan, and zibozentan, which—although Hôpital Européen Georges
system, endothelin receptors, and natriuretic peptide Pompidou APHP, Université Paris
exerting mild blood pressure-lowering effects—have been
Cité, Paris F-75015, France
signalling. Further more, innovative strategies for drug
evaluated only in proteinuric kidney diseases. Drugs michel.azizi@aphp.fr
delivery, such as RNA interference-based therapies, are
developed for other indications (eg, diabetes, obesity, heart
in late-phase trials (eg, zilbesiran [NCT07181109
failure, and chronic kidney disease)—notably SGLT2 inhibitors
NCT04936035, NCT05103332, and NCT06272487] and
and incretin therapies, GLP-1 receptor agonists, and dual
QCZ484 [NCT06857955]).
GLP-1–glucose dependent insulinotropic polypeptide
We herein review new drug therapies for hypertension
receptor agonists with complementary actions in lowering
in the context of targeting specific physiological systems.
blood pressure—are not covered here because none of these
Device-based therapies for uncontrolled hypertension7,8
drugs are currently licensed or recommended as
are beyond the scope of this Therapeutics review, but
antihypertensive agents. Finally, drugs that have only reached
have been recently reviewed elsewhere.10
phase 1 trials (eg, REGN5381), are in phase 2 trials for
indications other than hypertension (eg, soluble guanylate
RNA-based therapies for hypertension
cyclase stimulators), or initially showed promise in lowering
RNA-based therapies have successfully been developed for
blood pressure but did not show efficacy versus placebo in
conditions such as hypercholesterolaemia through
phase 2 or 3 trials (eg, IONIS-AGT-LRx, osilodrostat,
selective targeting of the RNA transcription of specific
ocedurenone, and firibastat) are reported only in the
proteins in the liver.11,12 These approaches now oer a new
appendix (p 3). See Online for appendix
therapeutic framework for hypertension by selectively
www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1 1
Therapeutics
unique substrate for renin, and its cleavage by renin to of the renin–angiotensin system than conventional
generate angiotensin 1 represents the rate-limiting step of oral angiotensin-converting enzyme (ACE) inhibitors
the renin–angiotensin system cascade.11–13 AGT gene and angiotensin receptor blockers (ARBs), and could
expression can be silenced by either synthetic double- improve adherence compared with daily oral therapies.
stranded small interfering RNAs (siRNAs) or single- Zilebesiran has been evaluated in patients with mild-
stranded antisense oligonucleotides, both of which, to-moderate hypertension who were either untreated or
through distinct mechanisms, cleave the complementary receiving a stable regimen of up to two antihypertensive
mRNA, thereby reducing protein translation.14,15 The first- agents in the phase 2, dose-ranging, KARDIA-1 trial.18 At
generation antisense oligonucleotide-targeting hepatic month 3, various subcutaneous injection doses of
angiotensinogen mRNA16 therapy was discontinued for zilebesiran (150–600 mg every 6 months) had clinically
lack of blood pressure-lowering ecacy (appendix p 3). significant reductions in 24 h ambulatory systolic blood
pressure relative to placebo—of about 15 mm Hg
Small interfering RNAs throughout the circadian cycle—and suppression in
Zilebesiran is the first-in-class trivalent serum angiotensinogen (>90%); the antihypertensive
N-acetylgalactosamine ligand-conjugated siRNA eect of zilebesiran was durable at 6 months (table 1).18
targeting hepatic angiotensinogen production, with In the phase 2 KARDIA-2 trial, a single 600 mg
other agents such as QCZ484 in development subcutaneous injection dose of zilebesiran as an add-on
(eg, NCT06857955). Zilebesiran is administered via therapy to monotherapies (indapamide, amlodipine, or
subcutaneous injection11,12,17 and is sequestered in late olmesartan) led to clinically significant 24 h systolic
hepatic endosomes, from which it is released slowly, blood pressure reductions at 3 months, particularly with
resulting in sustained suppression of angiotensinogen indapamide and amlodipine (table 1).19 However, the
production (a single administration can maintain ecacy phase 2 KARDIA-3 trial (NCT06272487), evaluating
for at least 6 months; figure).11,12 This approach zilebesiran as an add-on therapy in patients with
might provide more complete and durable inhibition uncontrolled hypertension and high cardiovascular risk,
Zilbesiran
Hepatocyte
ASGPR ASGPR
Recycling of ASGPR ASGPR Endosome
Cleavage and degradation
ASGPR of the angiotensinogen
Internalisation of the RISC mRNA
Degradation of the
GalNAc siRNA after
GalNAc moiety
binding to the ASGPR
mRNA cleavage
Release of
Removal of the passenger
angiotensinogen
(sense) strand
siRNA
RISC RISC RISC
Hybridisation of the guide
(antisense) strand with
angiotensinogen mRNA
Angiotensinogen
mRNA
Transcription
Genomic DNA
Figure: Mechanism of action of zilebesiran (double-stranded siRNA conjugated to trivalent GalNAc targeting angiotensinogen mRNA)
Zilebesiran is a first-in-class siRNA targeting hepatic angiotensinogen production.11,12 Zilebesiran has been chemically modified to optimise its pharmacokinetic,
pharmacodynamic, and safety profiles and is conjugated to trivalent GalNAc, which binds to ASGPR on hepatocytes, enabling targeted liver delivery. After receptor-
mediated endocytosis, siRNA escapes from endosomes into the cytosol and is incorporated into the RISC. The guide strand directs RISC to angiotensinogen mRNA,
leading to its cleavage (depicted by the thunderbolt symbol) and suppression of hepatic angiotensinogen synthesis. A single administration maintains efficacy for up
to 6 months.11,12 ASGPR=asialoglycoprotein receptor. GalNAc=N-acetylgalactosamine. RISC=RNA-induced silencing complex. siRNA=small interfering RNA.
2 www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1
Therapeutics
did not meet its primary blood pressure endpoint at around 11 000 patients with uncontrolled hypertension
3 months, probably due to a larger placebo eect than and high cardiovascular disease risk.21
in the earlier trials (table 1).20 Adverse events were
infrequent, mild, and reversible across the KARDIA Clinical considerations for RNA-based therapies for
trials (table 1). hypertension
On the basis of the KARDIA-3 trial, the zilebesiran An siRNA that specifically targets the degradation of
cardiovascular outcome study in hypertension phase 3 angiotensinogen mRNA in the hepatocyte oers a funda-
trial was designed to compare zilebesiran (300 mg via mentally new approach to manage hypertension with
subcutaneous injection every 6 months) with placebo in potential for twice-yearly dosing, particularly in patients
KARDIA-1 (phase 2, dose-ranging),18 n=394 KARDIA-2 (phase 2, add-on therapy),19 n=663 KARDIA-3 (phase 2, add-on therapy),20 n=663
Patient Patients with mild-to-moderate hypertension either Patients with uncontrolled hypertension despite receiving Patients with established cardiovascular
population untreated or receiving a stable regimen of up to one or two antihypertensive medications; 24 h ambulatory systolic disease, high cardiovascular risk or eGFR
two antihypertensive medications; daytime blood pressure of 130–160 mm Hg following washout of ≥30 to <60 mL/min per 1·73 m² and
ambulatory systolic blood pressure of 135–160 mm Hg background antihypertensive medications and a 4-week run-in uncontrolled hypertension on two to
following washout of background antihypertensive open-label treatment with indapamide 2·5 mg/day, amlodipine four antihypertensive medications (including a
medications 5 mg/day, or olmesartan 20–40 mg/day* calcium channel blocker or a diuretic); 24 h
ambulatory systolic blood pressure of
140–170 mm Hg; cohort A eGFR ≥45 mL/min
per 1·73 m²; and cohort B eGFR 30 mL/min per
1·73 m² to <45 mL/min per 1·73 m² (ongoing)
Intervention Zilebesiran (subcutaneous injection) 150 mg every Zilebesiran (subcutaneous injection) 600 mg vs placebo as a single Cohort A: zilebesiran (subcutaneous injection)
6 months, 300 mg every 6 months or every 3 months, dose 300 mg or 600 mg vs placebo as a single dose;
or 600 mg every 6 months, vs placebo cohort B: zilebesiran (subcutaneous injection)
150 mg, 300 mg or 600 mg vs placebo, as a
single dose (ongoing)
Trial duration 6 months 6 months 6 months
Primary Change in 24 h ambulatory systolic blood pressure at Change in 24 h ambulatory systolic blood pressure at month 3: Change in office systolic blood pressure at
endpoint month 3: −7·3 mm Hg with 150 mg, −10·0 mm Hg† −15·7 mm Hg with indapamide, −10·5 mm Hg with amlodipine, month 3†: −12·3 mm Hg with
with 300 mg, −8·9 mm Hg with 600 mg, and −7·7 mm Hg with olmesartan, and −3·7 mm Hg, −0·7 mm Hg, and 300 mg,−10·6 mm Hg with 600 mg, and
6·8 mm Hg with placebo; difference vs placebo: −3·2 mm Hg with placebo, respectively; difference vs placebo: −7·3 mm Hg with placebo; difference
−14·1 mm Hg (−19·2 to −9·0) with 150 mg, −12·1 mm Hg (−16·5 to −7·6) with indapamide, −9·7 mm Hg vs placebo‡: −5·0 mm Hg (−9·9 to −0·2) with
−16·7 mm Hg (−21·2 to −12·3)† with 300 mg, and (−12·9 to −6·6) with amlodipine, and −4·5 mm Hg (−8·2 to −0·8) 300 mg and −3·9 mm Hg (−8·2 to 1·0) with
−15·7 mm Hg (−20·8 to −10·6) with 600 mg with olmesartan 600 mg
Additional Change in office systolic blood pressure at month 3 Change in office systolic blood pressure at month 3 (difference Change in 24 h ambulatory systolic blood
endpoints (difference vs placebo): −9·6 mm Hg (−13·8 to −5·3) vs placebo): −18·5 mm Hg (−22·8 to −14·2) with indapamide, pressure at month 3‡ (difference vs placebo):
with 150 mg, −12·0 mm Hg (−15·7 to −8·3)† with −10·2 mm Hg (−13·4 to −6·9) with amlodipine, and −6·7 mm Hg −3·6 mm Hg (−7·7 to 0·4) with 300 mg and
300 mg, and −9·1 mm Hg (−13·4 to −4·8) with 600 mg; (−10·2 to −3·3) with olmesartan; time-adjusted change in 24 h −2·6 mm Hg (−6·7 to 1·6) with 600 mg; change
change in 24 h ambulatory systolic blood pressure at ambulatory systolic blood pressure through 6 months (difference in 24 h ambulatory systolic blood pressure at
6 months (difference vs placebo): −11·1 mm Hg vs placebo): −11·0 mm Hg (−14·7 to −7·3) with indapamide, month 6‡ (difference vs placebo): −5·5 mm Hg
(−15·8 to −6·4) with 150 mg, −14·5 mm Hg −7·9 mm Hg (−10·6 to −5·3) with amlodipine, and −1·8 mm Hg (−9·4 to −1·5) with 300 mg and −7·4 mm Hg
(−19·1 to −9·9)† with 300 mg, and −14·2 mm Hg (−4·6 to 1·0) with olmesartan; responder rate at month 6§: (−11·3 to −3·4) with 600 mg; responder rate at
(−18·9 to −9·5) with 600 mg; responder rate at 64·2% with indapamide vs 14·0% with placebo, 39·8% with month 6: not reported; rescue antihypertensive
month 6§: 30·8% with 150 mg, 50·7% every 6 months amlodipine vs 13·7% with placebo, and 26·0% with olmesartan medications at month 6: not reported;
and 38·7% every 3 months with 300 mg, 47·4% with vs 17·2% with placebo; rescue antihypertensive medications at angiotensinogen reduction: not reported
600 mg, and 6·7% with placebo; add-on use of at least month 6: 15·5% with indapamide vs 41·7% with placebo,
one antihypertensive medication through 6 months: 25·2% with amlodipine vs 48·7% with placebo, 42·5% with
32·1% with 150 mg, 20·5% every 6 months and 26·7% olmesartan vs 54·0% with placebo; angiotensinogen
every 3 months with 300 mg, 27·6% with 600 mg, and reduction: >95% (all groups)
52·0% with placebo; angiotensinogen reduction: >90%
(300 mg or 600 mg by month 6)
Key safety Hyperkalaemia: 6·3% in all zilebesiran groups vs 2·7% Hyperkalaemia >5·5 mmol/L: 6·1% in all zilebesiran groups vs 1·2% Hyperkalaemia >5·5 mmol/L‡: 4·4% with
observations with placebo; acute kidney failure: 1·0% in all with placebo (indapamide: 3·2%; amlodipine: 6·8%; and 300 mg, 8·8% with 600 mg; and 4·5% with
zilebesiran groups vs 0% with placebo; eGFR change at olmesartan: 6·7%); ≥30% decrease in eGFR: 8·5% in all zilebesiran placebo; eGFR decrease ≥30% and <60 mL/min
month 6: −1·5% with 150 mg, −2·9% every 6 months groups vs 3·0% with placebo (indapamide: 12·7%; per 1·73 m²‡: 5·5% with 300 mg, 8·8% with
and −2·7% every 3 months with 300 mg, −3·0% with amlodipine: 8·5%; and olmesartan: 6·8%); eGFR change at 600 mg, and 1·1% with placebo; eGFR change
600 mg, and −2·4% with placebo; hypotension: 4·0% in month 6: not reported; hypotension: 4·3% in all zilebesiran groups at month 6: not reported; hypotension‡:
all zilebesiran groups vs 0% with placebo; injection-site vs 2·1% with placebo (indapamide: 0%; amlodipine: 5·9%; and 3·3% with 300 mg; 4·4% with 600 mg;
reactions: 6·3% in all zilebesiran groups vs 1·0% with olmesartan: 4·7%); injection-site reactions: 3·0% in all zilebesiran 3·4% with placebo; injection-site reactions: not
placebo groups vs 0·3% with placebo (indapamide: 6·3%; amlodipine: 1·7%; reported
and olmesartan: 2·7%)
Changes in blood pressure are expressed as means, and differences vs placebo are expressed as mean (95% CI), unless otherwise stated. eGFR=estimated glomerular filtration rate. *Patients with eGFR
<45 mL/min per 1·73 m² or urine albumin–creatinine ratio >300 mg/g were preferentially assigned to olmesartan; the olmesartan dose was 20 mg for patients with eGFR ≤60 mL/min per 1·73 m² in countries
other than the USA. †Every 6 months or every 3 months dosing combined. ‡Cohort A only. §Defined as reaching a 24 h ambulatory systolic blood pressure <130 mm Hg, a ≥20 mm Hg reduction from baseline, or
both, without rescue medication.
Table 1: Blood pressure-lowering effects, angiotensinogen suppression, and key safety issues with zilebesiran in three phase 2 trials conducted in patients with hypertension
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for whom sustained and long-term blood pressure control concentrations, even in the setting of elevated plasma
is crucial but dicult to achieve with conventional renin.23 Furthermore, zilebesiran does not increase plasma
medications (appendix p 5). A key additional advantage to angiotensin 1–7 or activate the bradykinin–nitric oxide–
this approach is sustained adherence to treatment because cyclic guanosine monophosphate pathway, which have
therapy remains active for at least 6 months (appendix p 5). been speculated to contribute to the benefits of treatment
However, most patients would still require additional daily with ACE inhibitors or ARBs beyond their eect on blood
antihypertensive medications for optimal blood pressure pressure (appendix p 6)11,12 and to the bradykinin-dependent
control, as zilebesiran alone achieves 24 h ambulatory adverse eects of ACE inhibitors, notably cough,24 and,
blood pressure control in only about 50% of patients more rarely, angio-oedema.25 Finally, zilebesiran and other
(increasing to approximately 65% when combined with RNA-based therapies targeting angiotensinogen, which
indapamide; table 1). Even in patients with low adherence induce sustained angiotensin 2 suppression, might not
to conventional treatment, zilebesiran alone would still have the neuroprotective benefits specifically attributed to
provide an improvement in blood pressure control. The ARBs as compared with ACE inhibitors.26 The
prolonged duration of action of zilebesiran and consistent neuroprotective eects of ARBs have been attributed to
24 h ecacy for up to 24 weeks could make this treatment increased angiotensin 2 and redirected signalling to type-2
approach suitable for various types of patients with and type-4 angiotensin 2 receptors (appendix p 6), which
hypertension (table 2).11,12 A final point for consideration is have been shown experimentally to mitigate oxidative
the consequence of upstream inhibition of the renin– stress and neuroinflammation, improve cerebral
angiotensin system with siRNA targeting angiotensinogen perfusion, and reduce amyloid β accumulation and tau
(appendix p 6). Conventional renin–angiotensin system hyperphosphorylation.27
blockers provoke a counter-regulatory rise in plasma renin The eects of zilebesiran on serum potassium
concentration by disrupting angiotensin 2-mediated concentrations and estimated glomerular filtration rate
negative feedback at the level of the juxtaglomerular (eGFR) have been predictable and consistent with those
apparatus.22 In the presence of physiological circulating expected from renin–angiotensin system inhibition
concentrations of angiotensinogen, the compensatory rise (table 1). The risk of mild and reversible hyperkalaemia,
in renin can partly restore angiotensin 1 and 2 levels, as reported in the KARDIA trials, is similar to that from
blunting ecacy of oral conventional therapies. In conventional renin–angiotensin system inhibitors and
contrast, sustained depletion of angiotensinogen by a will be dependent on the patient population, and
siRNA prevents the increase in all angiotensin peptide increased in individuals with chronic kidney disease,
Potential indications Potential risks
RNA-based therapies targeting Patients with elevated cardiovascular and renal risk; patients Risk of adverse events shared with all other renin–angiotensin system blockers: excessive
angiotensinogen with very low adherence to treatment; patients with ACE hypotension and renal failure when blood pressure and renal function are renin-
inhibitor-related or ARB-related adverse events; patients with dependent* or when combined with conventional oral renin–angiotensin system
renin–angiotensin system-dependent target organ damage blockers (dual renin–angiotensin system blockade), hyperkalaemia, ionic disturbances in
such as left ventricular hypertrophy, endothelium dysfunction, patients with chronic kidney disease or when combined with other medications,
or early kidney damage (eg, microalbuminuria); Black patients; haematocrit decrease, or anaemia in patients with chronic kidney disease, and other
and patients with oestrogen-induced hypertension unexpected adverse events; contraindicated during pregnancy; specific adverse event
risks: permanent and continuous renin–angiotensin system blockade and need for rapid
reversal of the effect
Aldosterone-targeted therapies Patients with difficult-to-control hypertension including Risk of adverse events shared between aldosterone synthase inhibitors and non-steroidal
(aldosterone synthase inhibitors uncontrolled or resistant hypertension; patients with MRAs: hyperkalaemia (especially in patients with chronic kidney disease, diabetes, or
and non-steroidal MRAs) aldosterone dysregulation; patients with primary when combined with other medications); hyponatraemia, hypotension, and reduced
aldosteronism; patients with heart failure and low or preserved eGFR; contraindicated during pregnancy; specific adverse events risk with aldosterone
ejection fraction†; and patients with diabetes, obesity, or synthase inhibitors: hypocortisolism or hypercortisolism, and other unexpected adverse
chronic kidney disease and albuminuria† events
Endothelin 1 receptor antagonists Patients with resistant hypertension who are either intolerant Fluid retention, peripheral oedema, or both (caution is warranted in individuals with a
(aprocitentan‡) of MRAs or for whom MRAs are contraindicated history of heart failure); contraindicated during pregnancy
Sacubitril–valsartan§ Patients with resistant hypertension not responding to a Risk of adverse events shared with all other renin–angiotensin system blockers: excessive
conventional ARB included in a triple antihypertensive therapy hypotension and renal failure when blood pressure and renal function are renin-
including a diuretic; and patients with hypertension and heart dependent*, hyperkalaemia, ionic disturbances in patients with chronic kidney disease or
failure with low ejection fraction when combined with other medications, haematocrit decrease or anaemia in patients
with chronic kidney disease, pregnancy, and with other unexpected adverse events;
specific adverse events risks: angioedema (more in Black patients) especially if combined
with ACE inhibitors or dipeptidyl peptidase IV inhibitors
eGFR=estimated glomerular filtration rate. ACE=angiotensin converting enzyme. ARB=angiotensin receptor blocker. MRAs=mineralocorticoid receptor antagonists. *For example: elderly patients, salt depletion,
hypovolaemia, heat wave, use of cyclo-oxygenase enzyme inhibitors, presence of renal artery stenosis, anaesthetic induction, urgent surgery, haemorrhage, septic shock, or myocardial infarction. †Alone or in
combination with a SGLT2 inhibitor. ‡Aprocitentan is approved for the treatment of hypertension inadequately controlled by at least three antihypertensive medications in the USA, Europe, and the UK.
§Sacubitril–valsartan is approved for the treatment of hypertension only in Japan, China, and Russia.
Table 2: Potential indications and risks of new drug therapies for hypertension
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higher pre-treatment serum potassium concentrations, creatinine and potassium will be required to ensure safe
diabetes, or concomitant use of mineralocorticoid and eective use of siRNAs targeting angiotensinogen.
receptor antagonists (MRAs) or conventional renin– Their use will also necessitate thorough patient
angiotensin system inhibitors, necessitating more education, including regular use of self-measurement of
regular monitoring of serum potassium concentrations blood pressure at home, specific precautions especially
in these populations.28 In the KARDIA trials, which in case of volume depletion or pregnancy, and
enrolled patients with a mean baseline eGFR of contingency plans to manage acute scenarios. If ongoing
approximately 80 mL/min per 1·73 m², zilebesiran was phase 2 and 3 trials (eg, NCT06423352, NCT06905327,
associated with a mild initial decline in eGFR, similar to NCT06864104, and NCT07181109) confirm the long-term
that observed with conventional renin–angiotensin ecacy and safety of zilebesiran and other treatments in
system blockers.29 As an upstream renin–angiotensin this new class of therapy, they have the potential to oer
system inhibitor, this eect reflects a renal haemodynamic a durable, infrequent injection-based therapy for
mechanism: reduced intraglomerular pressure due to hypertension, potentially reshaping future treatment
decreased transmission of elevated systemic blood frameworks.
pressure into the aerent arteriole resulting from
improved hypertension control, together with eerent Aldosterone-targeted therapies
arteriolar vasodilatation due to angiotensin 2 Aldosterone is a mineralocorticoid hormone mainly
suppression.30 The long-term consequences of this early produced by the glomerulosa cells of the outer zone of
eGFR decline in patients with lower baseline eGFR are the adrenal cortex in response to multiple stimuli
yet to be established.31 including hypotension, hyperkalaemia, angiotensin 2,
A unique clinical challenge with the long-lasting, and adrenocorticotrophic hormone.35,36 In the kidney,
siRNA-mediated inhibition of the renin–angiotensin aldosterone acts via its mineralocorticoid receptor to
system is the inability to expediently reverse the siRNA enhance reabsorption of sodium and fluid and increase
mechanism and resulting renin–angiotensin system potassium excretion.35,36 In addition, aldosterone
suppression in emergencies in which the renin– activates expression of multiple pro-inflammatory and
angiotensin system is usually activated to maintain blood profibrotic mediators in the kidneys and heart.35,36
pressure and circulating volume (eg, in patients with Aldosterone also can mediate non-genomic and
shock or acute volume depletion).32 In these emergency mineralocorticoid receptor-independent mechanisms
situations, countermeasures should include intravenous that contribute to endothelial dysfunction, vascular
fluids and intravenous angiotensin 2 or vasopressor stiness, and systemic vasoconstriction.37 In treatment-
administration if required. Moreover, administration of resistant hypertension characterised by a blood pressure
zilebesiran to patients with undetected renal artery level remaining above threshold despite a triple
stenosis could pose a risk of acute kidney injury, similar combination antihypertensive therapy at maximally
to that observed with ACE inhibitors and ARBs, but less tolerated doses including a diuretic, the steroidal MRA
reversible due to the long-acting nature of the therapy— spironolactone is recommended as a preferred fourth-
underscoring the need for a reliable reversal strategy for line therapy if eGFR is above 30 mL/min per 1·73 m²
this kind of scenario. Preclinical studies have shown that and serum potassium is below 4·5 mmol/L,7,8,38 and its
a complementary REVERSIR subcutaneous injection—a benefits in heart failure with reduced ejection fraction
specific siRNA designed to hybridise with and inactivate are well recognised.39,40 However, spironolactone is
the RISC-loaded siRNA—can restore angiotensinogen underused due to concerns over hyperkalaemia
mRNA production and blood pressure within 48 h in (especially in chronic kidney disease)41 and anti-
rats.33 Although this complementary treatment will not androgenic and progestogenic adverse events.42 Another
be of use in an emergency setting (because the onset of steroidal MRA, eplerenone, which does not interfere
reversal takes too long), reversal agents could be of use with progesterone or androgen receptors, can be used
for patients in whom long-lasting renin–angiotensin alternatively,7,8 but is less eective in lowering blood
system inhibition is no longer desirable. pressure than spironolactone.43 However, there has been
Pregnancy represents another crucial concern. an increasing recognition among clinicians and
Angiotensinogen concentrations rise during pregnancy researchers that many patients with hypertension are
to support uteroplacental blood flow and maternal blood likely to have some degree of aldosterone dysregulation
pressure regulation,34 and an siRNA targeting angio- (ie, renin-independent aldosterone production that is
tensinogen could theoretically pose risks of maternal excessive relative to the sodium status of the patient).
hypotension and placental insuciency. Eective This dysregulation spans a spectrum, with increasing
contraception should be recommended for women of severity associated with a higher prevalence of dicult-
childbearing potential when receiving an siRNA targeting to-control and resistant hypertension; overt primary
angiotensinogen. aldosteronism represents the extreme end of this
Given these considerations, careful patient selection spectrum.44–46 Therefore, the need to eectively target the
and attention to baseline and post-treatment serum aldosterone–mineralocorticoid receptor pathway to
www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1 5
Therapeutics
mitigate hypertension and to preserve organ function in duration of action, slow oset, and no rebound eect
patients with heart failure and chronic kidney disease, upon withdrawal. In patients with chronic kidney disease
while improving tolerability of therapy, has motivated (with a mean eGFR 44 mL/min per 1·73 m² and median
the development of two classes of aldosterone-targeted urinary albumin-to-creatinine ratio [UACR] 714 mg/g)
therapies: aldosterone synthase (CYP11B2) inhibitors and uncontrolled hypertension, baxdrostat lowered both
and non-steroidal MRAs, as well as their use in oce systolic blood pressure and UACR compared with
combination with SGLT2 inhibitors for patients with, or placebo, but at the cost of high rates of hyperkalaemia
at risk of, heart failure or chronic kidney disease. (appendix p 7).55 Finally, in a small phase 2a open-label
study in 15 patients with primary aldosteronism,57
Aldosterone synthase inhibitors baxdrostat reduced systolic blood pressure and excessive
Aldosterone escape is a well recognised compensatory aldosterone production and corrected hypokalaemia
response to chronic inhibition of the renin–angiotensin (appendix p 7).
system by ACE inhibitors or ARBs, and mineralcorticoid Adverse events with baxdrostat or lorundrostat were
receptor bloackade due, in part, to the counter-regulatory mild, infrequent, and reversible across the trials, and
increase in renin levels induced by all these drugs via were predictable on the basis of the anticipated eects of
dierent mechanisms (eg, interruption of the aldosterone synthase inhibition, including hyperkalaemia
angiontensin 2 feedback loop on renin secretion for both and hyponatraemia (table 3).49,51–54 Hyperkalaemia rates
ACE inhibitors and ARBs, and sodium depletion induced were much higher in patients with chronic kidney
by MRAs), which partly counteracts their beneficial disease (41%) compared with patients in the placebo
actions.47 Inhibition of aldosterone synthase in the adrenal group (5%; appendix p 7).55 No cases of hypercortisolism
cortex is an attractive therapeutic strategy, as it could or adrenal insuciency were reported in the baxdrostat
circumvent aldosterone escape and enhance ecacy by or lorundrostat trials.49,51–54
attenuating both genomic and non-genomic actions of Another ASI, dexfadrostat phosphate (which has a
aldosterone.37 The pharmacological challenge has been CYP11B2-to-CYP11B1 selectivity ratio of 9),48 was
overcoming the close homology (>93%) between assessed in a small, proof-of-concept study in patients
aldosterone synthase (CYP11B2) and cortisol synthase with primary aldosteronism.58 Dexfadrostat phosphate
(CYP11B1), to enable selective inhibition of the former reduced the aldosterone–renin ratio, aldosterone levels,
without inhibiting the latter.48 and both ambulatory and oce systolic blood pressure
Second-generation aldosterone synthase inhibitors (appendix p 7).58 To our knowledge, at the time of
(ASIs) developed to augment selectivity for aldosterone writing, no further trials with this aldosterone synthase
synthase (CYP11B2) over cortisol synthase (CYP11B1) inhibitor are planned.
include baxdrostat, lorundrostat, defaxadrostat, and After a small phase 1 proof-of-concept study,61 vicadrostat
vicadrostat.48 These ASIs have completed phase 2 and 3 (BI 690517), another highly selective ASI (CYP11B2-to-
trials,49–59 although another compound (LY3045697) failed CYP11B1 selectivity ratio of 250),62 was evaluated in a
to move forward because of the loss of its eects with phase 2, placebo-controlled study assessing the ecacy
multiple dosing.60 and safety of multiple oral doses alone or in combination
Both baxdrostat and lorundrostat (which have CYP11B2 with the SGLT2 inhibitor empagliflozin in participants
and CYP11B1 selectivity ratios of 100 and 374, with chronic kidney disease (mean eGFR 52 mL/min per
respectively)48 have been evaluated for the treatment of 1·73 m² and median UACR 426 mg/g), with or without
uncontrolled and resistant hypertension in placebo- type 2 diabetes, receiving stable background ARB or ACE
controlled phase 2 and 3 trials over a large dose range inhibitor (appendix p 7).59 Vicadrostat alone reduced the
(table 3).49–55 When added to a background therapy UACR and systolic blood pressure at 14 weeks in a dose-
of two or more antihypertensive medications, the dependent manner, with more pronounced eects
placebo-corrected blood pressure-lowering eects of both observed when combined with empagliflozin (appendix
drugs (at 6, 8, or 12 weeks) were consistent and clinically p 7). Adverse events were infrequent (appendix p 7),
relevant (table 3), with the exception of the HALO trial of although smaller increases in serum potassium
baxdrostat,50,56 which did not meet its primary blood concentrations occurred with vicadrostat in combination
pressure endpoint, possibly because of a large placebo with empagliflozin, compared with vicadrostat alone.59
eect (NCT05137002; results presented50 but not yet There are ongoing phase 3 trials of ASIs in hypertension
published at the time of writing). Both baxdrostat and (appendix p 10). Moreover, large, phase 3 outcome trials
lorundrostat also produced dose-dependent decreases in currently in progress for chronic kidney disease and
serum aldosterone concentrations (table 3) and increases heart failure are testing combinations of an ASI plus an
in plasma renin activity, but did not decrease basal serum SGLT2 inhibitor (appendix p 10).
cortisol levels.49–55 Of note, in the phase 3 BaxHTN trial,54
systolic blood pressure continued to decline during an Non-steroidal mineralocorticoid receptor antagonists
8-week randomised withdrawal period with baxdrostat Mineralocorticoid receptor antagonists include
(increasing slightly with placebo), indicating a long two distinct classes: steroidal MRAs (eg, spironolactone
6 www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1
Therapeutics
www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1 7
,)3 esahp(⁹⁵NTH−hcnuaL
,)2 esahp( ⁸⁵NTH−ecnavdA
002=n ,)2 esahp( ⁷⁵NTH−tegraT
497=n ,)3 esahp( ⁰⁶NTHxaB
942=n
,)2 esahp( ⁶⁵lairt OLAH
572=n ,)2 esahp( ⁵⁵NTHgirB
3801=n
582=n
tnatsiser ro dellortnocnU
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noisnetrepyh dellortnocnU
noisnetrepyh dellortnocnU
elihw
noisnetrepyh dellortnocnU
noisnetrepyh tnatsiseR
tneitaP
owt etipsed noisnetrepyh
ot owt etipsed noisnetrepyh
evisnetrepyhitna owt tsael ta etipsed
evisnetrepyhitna owt etipsed
ro
,BRA
ro rotibihni ECA na gnikat
tsael ta etipsed
noitalupop
evisnetrepyhitna evfi
ot
evisnetrepyhitna evfi
;sesod detarelot mumixam ta snoitacidem
tnatsiser ro snoitacidem
a sulp
BRA ro rotibihni ECA na
evisnetrepyhitna eerht
ecffio ;snoitacidem
yrotalubma h 42 ;snoitacidem
gH mm 031≥ erusserp doolb cilotsys ecffio
tsael ta etipsed noisnetrepyh
ECA na ro ,citeruid edizaiht
a gnidulcni snoitacidem
erusserp doolb cilotsys
erusserp doolb cilotsys
sulp obecalp no doirep ni-nur keew-2 retfa
evisnetrepyhitna eerht
muiclac
a sulp BRA ro rotibihni
erusserp doolb ecffio ;citeruid
dna gH mm 081−531
h 42 ro gH mm 081−031
snoitacidem evisnetrepyhitna dnuorgkcab
a gnidulcni ,snoitacidem
cilotsys
ecffio ;rekcolb lennahc
keew-2 retfa gH mm 08/031≥
erusserp doolb cilotsaid
doolb cilotsaid yrotalubma
ecffio ;sesac htob ni citeruid
retfa
gH
mm 041≥ erusserp doolb
sulp obecalp no doirep ni-nur
ro gH mm 011−56
retfa gH mm 08> erusserp
erusserp doolb cilotsys
obecalp
no doirep ni-nur keew-4–2
evisnetrepyhitna dnuorgkcab
erusserp doolb cilotsaid
no doirep ni-nur keew-3
keew-2 retfa gH mm 531≥
evisnetrepyhitna
dnuorgkcab sulp
snoitacidem
retfa gH mm 011−09
desidradnats sulp obecalp
sulp obecalp no doirep ni-nur
snoitacidem
no doirep ni-nur keew-2
snoitacidem evisnetrepyhitna
evisnetrepyhitna dnuorgkcab
dnuorgkcab sulp obecalp
edizaiht a sulp natrasemlo ,ei(
snoitacidem
evisnetrepyhitna
tuohtiw ro htiw citeruid
snoitacidem
)enipidolma
gm 05 :tatsordnuroL
rof yliad gm 05 :tatsordnuroL
eciwt gm 5·21 ,yliad gm 5·21 :tatsordnuroL
gm 2 ro yliad gm 1 :tatsordxaB
gm
1 ,yliad gm 5·0 :tatsordxaB
,yliad gm 5·0 :tatsordxaB
noitnevretnI
ro ,skeew 21 rof yliad
rof yliad gm 05 ro ,skeew 21
gm 001 ro ,yliad gm 05 ,yliad eciwt gm 52 ,yliad
obecalp sv yliad
obecalp
sv yliad gm 2 ro ,yliad
yliad gm 2 ro ,yliad gm
skeew 6 rof yliad gm
ot noitartit htiw skeew 4
obecalp sv yliad
obecalp
sv
gm 001 ot noitartit htiw
skeew 8 rof yliad gm 001
skeew 6 rof yliad
esod htiw tatsordnurol(
esod htiw tatsordnurol(
obecalp sv )tnemtsujda
obecalp sv )tnemtsujda skeew
skeew 21
skeew
skeew
skeew 8
skeew
noitarud
lairT
)yramirp(
cilotsys ecffio ni egnahC
yrotalubma h 42 ni egnahC
:erusserp doolb cilotsys ecffio ni egnahC
doolb cilotsys ecffio ni egnahC
doolb
cilotsys ecffio ni egnahC
doolb cilotsys ecffio ni egnahC
yramirP
:erusserp doolb
:erusserp doolb cilotsys
,gm 5·21 tatsordnurol htiw gH mm 6·5−
htiw gH mm 5·41– :erusserp
htiw
gH mm 0·71− :erusserp
htiw gH mm 1·21− :erusserp
tniopdne
htiw gH mm 9·61−
htiw gH mm 4·51−
tatsordnurol htiw gH mm 3·11−
gH mm 7·51– ,gm 1 tatsordxab
gH
mm
0·61− ;gm 5·0 tatsordxab
,gm 5·0 tatsordxab
dna ,gm 05 tatsordnurol
,gm 05 tatsordnurol
htiw gH mm 1·11− ,yliad eciwt gm 5·21
dna ,gm 2 tatsordxab htiw
,gm 1 tatsordxab htiw
tatsordxab htiw gH mm 5·71−
htiw gH mm 9·7−
htiw gH mm 9·31−
gH mm 7·31− ,yliad eciwt gm 52 tatsordnurol
;obecalp htiw gH mm 8·5–
tatsordxab
htiw gH mm 8·91−
htiw gH mm 3·02−,gm
ecnereffid ;obecalp
esod htiw tatsordnurol
htiw gH mm 9·11− ,gm 05 tatsordnurol htiw
:obecalp sv ecnereffid
htiw
gH mm 6·61− dna ,gm 2
dna ,gm 2 tatsordxab
gH mm 1·9− :obecalp
sv
gH mm 9·7− dna ,tnemtsujda
htiw gH mm 1·4− ,gm 001 tatsordnurol
)8·5− ot 5·11 −( gH mm 7·8–
obecalp
sv ecnereffid ;obecalp
;obecalp htiw gH mm 4·9−
htiw )9·4− ot 3·31−(
ecnereffid ;obecalp htiw
:)]IC %09[ naem( obecalp sv ecnereffid ;obecalp
dna ,gm 1 tatsordxab htiw
)12·2±(
gH mm 5·0− :†)]ES[ naem(
:obecalp sv ecnereffid
gm 05 tatsordnurol
:)]IC %5·79[ naem( obecalp sv
tatsordnurol htiw )3·5 ot 3·8−( gH mm 5·1−
)0·7− ot 6·21 −( gH mm 8·9–
,gm 5·0 tatsordxab htiw
*)7·2 ot 6·8−( gH mm 0·3−
)6·2− ot 3·31−( gH mm 9·7−
htiw )4·0− ot 0·41−( gH mm 2·7− ,gm 5·21
gm 2 tatsordxab htiw
htiw )02·2±( gH mm 6·0
,gm 5·0 tatsordxab htiw
dna ,gm 05 tatsordnurol htiw
gH mm 0·7− ,yliad eciwt gm 5·21 tatsordnurol
gH
mm
2·3− dna ,gm 1 tatsordxab
)8·2− ot 5·31−( gH mm 1·8−
)2·1− ot 8·11−( gH mm 5·6−
tatsordnurol htiw )8·0− ot 1·31−(
gm
2 tatsordxab htiw )32·2±(
dna ,gm 1 tatsordxab htiw
esod htiw tatsordnurol htiw
)4·3− ot 8·51−( gH mm 6·9− ,yliad eciwt gm
)5·5− ot 4·61−( gH mm 0·11−
tnemtsujda
gH mm 8·7−dna ,gm 05 tatsordnurol htiw
gm 2 tatsordxab htiw
gm 001 tatsordnurol htiw )5·1− ot 1·41−(
rednopser erusserp doolB
etar rednopser erusserp doolB
doolb cilotsys( etar rednopser erusserp doolB
etar rednopser erusserp doolB
etar
rednopser erusserp doolB
rednopser erusserp doolB
lanoitiddA
doolb cilotsys( etar
yrotalubma h 42( 4 keew ta
htiw %1·62 :)gH mm 08/031< erusserp
erusserp doolb cilotsys(
erusserp doolb cilotsys(
ni egnahc ;detroper ton :etar
stniopdne
:)gH mm 031< erusserp
erusserp doolb cilotsys
tatsordnurol htiw %8·13 ,gm 5·21 tatsordnurol
htiw %4·93 :)gH mm 031<
htiw %1·75 :)gH mm 031<
–enoretsodla yraniru
eht
tatsordnurol htiw %1·44
htiw %0·14 :)gH mm 521<
tatsordnurol htiw %3·34 ,yliad eciwt gm 5·21
htiw %0·04 ,gm 1 tatsordxab
htiw
%2·35 ,gm 5·0 tatsordxab
g/gn 781− :oitar eninitaerc
htiw %1·42 dna ,gm
dna ,)deloop( tatsordnurol
tatsordnurol htiw %9·24 ,yliad eciwt gm
dna ,gm 2 tatsordxab
htiw
%7·17 ,gm 1 tatsordxab
,gm 5·0 tatsordxab htiw
mures ni egnahc ;obecalp
ni egnahc ;obecalp htiw %0·81
dna ,gm 001 tatsordnurol htiw %0·03 ,gm
ni egnahc ;obecalp htiw %7·81
htiw
%3·65
dna ,gm 2 tatsordxab
tatsordxab htiw g/gn 081−
ton :enoretsodla
:enoretsodla mures
mures ni egnahc ;obecalp htiw %3·32
:enoretsodla mures
mures ni egnahc ;obecalp
htiw g/gn 372− ,gm
detroper
tatsordnurol htiw %7·74−
htiw %9·41− :4 keew ta enoretsodla
,gm 1 tatsordxab htiw %9·95−
htiw %3·04− :enoretsodla
g/gn 6 dna ,gm 2 tatsordxab
htiw %7·55− ,gm 05
htiw %1·63− ,gm 5·21 tatsordnurol
,gm 2 tatsordxab htiw %4·56−
htiw
%3·14− ,gm 5·0 tatsordxab
obecalp htiw
esod htiw tatsordnurol
htiw %6·15− ,yliad eciwt gm 5·21 tatsordnurol
obecalp htiw egnahc
on
htiw
%8·93− ,gm 1 tatsordxab
htiw %5·22 dna ,tnemtsujda
htiw %2·14− ,yliad eciwt gm 52 tatsordnurol
htiw
%7·01−
dna ,gm 2 tatsordxab
obecalp
tatsordnurol htiw %8·34− ,gm 05 tatsordnurol
obecalp
obecalp htiw %2·2 dna ,gm 001
)egap txen no seunitnoc
elbaT(
Therapeutics
8 www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1
,)3
esahp(⁹⁵NTH−hcnuaL
,)2 esahp(
⁸⁵NTH−ecnavdA
002=n ,)2 esahp(
⁷⁵NTH−tegraT
497=n ,)3 esahp( ⁰⁶NTHxaB
942=n ,)2 esahp( ⁶⁵lairt OLAH
572=n ,)2 esahp( ⁵⁵NTHgirB
3801=n
582=n
)egap suoiverp
morf
deunitnoC(
aimealakrepyH
,L/lomm
6≥ aimealakrepyH
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6≥
aimealakrepyH
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htiw 0 :)%( n ,aimealakrepyH
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:)%(
n ,L/lomm
6≥
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5 :)%(
n
,gm 5·21 tatsordnurol
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n
htiw
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n
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htiw
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htiw )%0·3( 2 ,gm 5·0
,gm
05 tatsordnurol
tatsordnurol
htiw
)%0·7(
,yliad eciwt gm 52 tatsordnurol
htiw
)%0·3( 1
tatsordxab htiw )%0·3(
dna ,gm 2 tatsordxab
,gm 1 tatsordxab
htiw
)%5·1(
dna ,tnemtsujda
esod htiw
,gm 05 tatsordnurol
htiw
)%0·4( 1
htiw )%4·0( 1 dna
,gm
;obecalp htiw )%6·1(
tatsordxab htiw )%0·2(
esod htiw
tatsordnurol
aimealakrepyh
;obecalp
htiw
htiw
0 dna ,gm 001 tatsordnurol
htiw
)%0·3( 1
aimealakrepyh ;obecalp
htiw 0 :)%( n ,aimeartanopyh
;obecalp htiw 0 dna ,gm
dna ,tnemtsujda
:)%(
n ,L/lomm
9·5–5·5
:)%(
n ,L/lomm 9·5–5·5 aimealakrepyh
;obecalp
:)%( n ,L/lomm 9·5–5·5
htiw 0 ,gm 5·0 tatsordxab
aimealakrepyh
;obecalp
htiw
)%7·0(
tatsordnurol
htiw
)%0·6(
,gm 5·21 tatsordnurol
htiw
)%0·31( 3
tatsordxab htiw )%1·6(
htiw )%7·1( 1 ,gm 1 tatsordxab
:)%( n ,L/lomm 9·5–5·5
aimealakrepyh
htiw
)%0·11(
01 ,gm
,yliad
eciwt gm 5·21 tatsordnurol
htiw
)%0·9( 2
htiw )%1·11( 92
,gm
htiw 0 dna ,gm 2 tatsordxab
tatsordxab htiw )%0·1(
:)%( n
,L/lomm
9·5–5·5
esod
htiw tatsordnurol
,yliad eciwt gm 52 tatsordnurol
htiw
)%0·7( 2
dna ,gm 2 tatsordxab
aimeartanopyh ;obecalp
htiw )%0·3( 2 ,gm 5·0
htiw
)%1·7(
htiw )%0·3(
3 dna ,tnemtsujda
,gm 05 tatsordnurol
htiw
)%0·4( 1
;obecalp htiw )%4·0(
;detroper
ton :)%( n ,L/lomm 531<
,gm 1 tatsordxab
,gm
05 tatsordnurol
aimeartanopyh
;obecalp
dna ,gm 001 tatsordnurol
htiw
)%0·61( 5
,L/lomm 531< aimeartanopyh
;detroper
ton :ycneicffiusni lanerda
tatsordxab htiw )%0·2(
htiw )%7·01(
:)%( n ,L/lomm
531<
,L/lomm
531< ,aimeartanopyh
;obecalp
htiw 0
htiw )%1·91( 94
;)%(
n
,muissatop mures ni egnahc
;obecalp htiw 0 dna ,gm
esod htiw
tatsordnurol
tatsordnurol
htiw
)%0·9(
;enon
:ycneicffiusni lanerda
;detroper
ton :)%( n
,gm 1 tatsordxab
ni
egnahc ;detroper ton :L/lomm
deriuqer taht aimeartanopyh
dna ,tnemtsujda
htiw
)%0·11(
01 ,gm
htiw
13·0 :L/lomm ,muissatop
mures
ni egnahc
tatsordxab htiw )%8·22(
ton :²m 37·1 rep nim/Lm ,RFGe
:)%( n ,noitnevretni lacinilc
;obecalp
htiw
)%1·1(
esod
htiw tatsordnurol
tatsordnurol htiw 23·0 ,gm
5·21
tatsordnurol
htiw )%0·7( 81 dna
,gm
detroper
,gm 5·0 tatsordxab htiw
aimeartanopyh
htiw )%0·6(
6 dna ,tnemtsujda
tatsordnurol htiw 43·0
,yliad
eciwt
gm 5·21
ni esaerced %03≥ ;obecalp
tatsordxab htiw )%0·3(
:)%(
n ,L/lomm
531<
ni esaerced
%52≥
;obecalp
tatsordnurol htiw 52·0
,yliad
eciwt
gm 52
tatsordxab htiw %6·21
:RFGe
htiw )%0·2( 1 ,gm
htiw
)%9·6(
rep nim/Lm
03< RFGe
ro RFGe
dna ,gm 001 tatsordnurol
htiw
92·0
,gm 05
tatsordxab htiw %6·51
,gm
htiw 0 dna ,gm 2 tatsordxab
,gm
05 tatsordnurol
htiw
)%0·3(
3 :²m 37·1
nim/Lm ,RFGe ni egnahc
;obecalp
htiw 30·0
;obecalp htiw %5·1 dna
,gm
:ycneicffiusni lanerda ;obecalp
htiw )%4·01(
,gm 05 tatsordnurol
,gm 5·21 tatsordnurol htiw
7·3−
:²m
37·1 rep
;enon :ycneicffiusni lanerda
mures ni egnahc ;enon
esod htiw
tatsordnurol
tatsordnurol
htiw
)%0·7(
,yliad eciwt gm 5·21 tatsordnurol
htiw 7·6−
,muissatop mures ni egnahc
htiw 91·0 :L/lomm ,muissatop
dna ,tnemtsujda
dna ,tnemtsujda
esod htiw
,yliad eciwt gm 52 tatsordnurol
htiw 6·5−
yletamixorppa :‡L/lomm
htiw 63·0 ,gm 5·0 tatsordxab
;obecalp
htiw
)%3·3(
lanerda ;obecalp
htiw
)%0·3(
htiw 8·7− ,gm 05 tatsordnurol
htiw 6·4−
,gm 1 tatsordxab htiw
03·0
htiw 92·0 ,gm 1 tatsordxab
:ycneicfied
diocitrococulg
ni egnahc
;enon :ycneicffiusni
obecalp htiw 9·0 dna ,gm
tatsordnurol
htiw 04·0 yletamixorppa
dna ,gm 2 tatsordxab
tatsordnurol
htiw
:L/lomm
,muissatop
mures
dna ,gm 2 tatsordxab
ni egnahc ;obecalp htiw 80·0−
htiw
0 ,gm
,gm 05 tatsordnurol
htiw 95·0
obecalp htiw 0 yletamixorppa
:²m 37·1 rep nim/Lm ,RFGe
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Therapeutics
and eplerenone), and non-steroidal MRAs (eg, finerenone Additionally, mild, early decreases in eGFR (<30%)
and esaxerenone) which have dierent chemical were observed in the trials of baxdrostat, lorundrostat,
structures and exhibit greater receptor selectivity and and vicadrostat at 8–14 weeks (table 3, appendix p 7), but
more complete antagonism than steroidal agents.42 were shown to be reversible upon drug discontinuation.54
Esaxerenone has showed eective blood pressure Similarly, in trials of both esaxerenone and finerenone,
reduction across a broad range of patients with untreated decreases in eGFR have been observed, although in the
hypertension, primary aldosteronism, and chronic kidney context of ultimate improvement in kidney outcomes.64
disease, but is currently available only in Japan (appendix Consequently, monitoring of serum potassium and
p 11).63 creatinine, especially within the first 2 weeks of initiating
Finerenone has been evaluated primarily for chronic therapy, will be necessary when ASIs will become
kidney disease and cardiovascular indications. In phase 2 commercially available, as is currently recommended for
and 3 trials in patients with chronic kidney disease or MRAs. Of note, in patients with chronic kidney disease,
heart failure, finerenone produced modest systolic blood the combined use of SGLT2 inhibitors might partly
pressure decreases in the range of 2–5 mm Hg with doses mitigate the risk of hyperkalaemia.59,71
between 10 mg and 20 mg daily, compared with placebo Finally, a legitimate initial concern for the ASI class is
when added to background renin–angiotensin system in relation to potential risks of both hypocortisolism and
inhibitor therapy.64–68 Compared with other MRAs, hypercortisolism—the former resulting from direct
finerenone appears to lower blood pressure less than inhibition of cortisol synthesis and the latter due to
spironolactone, albeit to a similar extent as eplerenone, shunting precursor metabolites toward cortisol
but finerenone is not licensed for the treatment of synthesis.48 Importantly, however, these adverse eects
hypertension.69,70 have not yet been reported with these highly selective
Finally, as for ASIs, ongoing studies are evaluating the ASIs at the doses tested for clinical use.
combination of finerenone and other steroidal MRAs The development of highly selective ASIs has shown
with SGLT2 inhibitors to assess their long-term benefits that this treatment approach is feasible in various clinical
on cardiovascular and kidney outcomes (appendix p 10). settings without excess risk, paving the way to further
In patients with chronic kidney disease and type 2 investigate their ecacy and safety in patients with a
diabetes receiving a renin–angiotensin system inhibitor, wide spectrum of hypertension that might relate to
6 months of treatment with a combination of finerenone aldosterone dysregulation, primary aldosteronism,
and empagliflozin resulted in a clinically significantly chronic kidney disease, or heart failure (table 2). How
greater reduction in UACR and systolic blood pressure ASIs compare with MRAs in terms of ecacy, tolerability,
than either agent alone, and was associated with a slightly and safety is unknown due to the absence of head-to-
lower incidence of serum potassium concentrations head trials across various clinical conditions.74
greater than 5·0 mmol/L.71
Endothelin-targeted therapy
Clinical considerations for ASIs and MRAs for Endothelin-1 is one of the most potent vasoconstrictors
hypertension implicated in the pathogenesis of both hypertension and
Because both ASIs and MRAs (steroidal and non-steroidal) chronic kidney disease.75,76 Endothelin-1 exerts its eects
inhibit the aldosterone pathway (although at two dierent through two G protein-coupled receptors widely
steps), similar safety concerns arise with their use. An distributed across multiple organ systems: the
increased risk of hyperkalaemia, in particular, could be endothelin receptor type A, primarily expressed on
underestimated because patients with higher serum vascular smooth muscle cells, which mediates
potassium concentrations and lower eGFR have been vasoconstriction and fibrosis; and the endothelin
excluded from most ASI and MRA trials to date. The rate receptor type B, located on endothelial cells (where it
of hyperkalaemia might be higher in clinical practice, promotes vasodilation via nitric oxide release) and on
depending on residual aldosterone production, basal kidney tubular epithelial cells and vascular smooth
eGFR, comor bidities, and concomitant medications.72 A muscle.75,76 In the setting of hypertension and chronic
pooled analysis of the 18 991 participants across the kidney disease, endothelin-1 expression is upregulated,
three phase 3 finerenone trials in patients with type 2 which provides a strong rationale for blockade of
diabetes and chronic kidney disease or heart failure endothelin-1 signalling to reduce blood pressure and
showed that finerenone was associated with an slow chronic kidney disease progression.75,76 Endothelin
approximately doubled risk of hyperkalaemia compared receptor antagonists (ERAs) can be either selective to the
with placebo, with 16·5% of patients having a potassium endothelin receptor type A, or act as antagonists to both
concentration greater than 5·5 mmol/L and 3·3% with the endothelin receptor type A and the endothelin
greater than 6·0 mmol/L.73 Hyperkalaemia rates were also receptor type B (dual ERAs).
higher in patients with chronic kidney disease who Even though the first dual ERAs (ie, bosentan and
received baxdrostat compared with placebo in a phase 2a darusentan) showed significant blood pressure
study (table 3).55 reductions in patients with hypertension, their
www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1 9
Therapeutics
development was discontinued due to adverse events, contraindicated during pregnancy. Caution is warranted
including fluid overload, peripheral oedema, and in individuals with a history of heart failure.
hepatotoxicity.77,78 Dose-related fluid retention (eg, peripheral oedema,
Aprocitentan, another dual ERA, was later developed weight gain, and heart failure) remains a key treatment-
for treatment of hypertension. After an 8-week, phase 2, limiting adverse eect of ERAs, particularly in patients
dose-finding trial (table 4),79 aprocitentan was evaluated in with chronic kidney disease or pre-existing cardiovascular
a large phase 3 study conducted in patients with resistant disease.76 Fluid retention, peripheral oedema, or both were
hypertension, all of whom were maintained on a triple the most frequently reported adverse events with
fixed-dose combination in a single pill of guideline- aprocitentan (table 4),80 which is also a concern especially
directed therapy.80 At 4 weeks, systolic blood pressure was in the context of resistant hypertension, which is
clinically significantly reduced with aprocitentan at often a sodium-retaining state. The underlying mech-
12·5 mg and 25 mg versus placebo, and the reduction anisms of fluid retention are multifactorial and
was sustained through 48 weeks at the 25 mg dose incompletely understood. Management strategies include
(table 4). co-administration or increase in dose of diuretics as part of
the background antihypertensive medications.80 In patients
Clinical implications for ERAs for hypertension with chronic kidney disease, the lowest available dose of
Aprocitentan is approved in the USA, Europe, and aprocitentan should be considered. Combining ERAs with
the UK for the treatment of hypertension inadequately SGLT2 inhibitors could oer additional benefit, mitigating
controlled by at least three antihypertensive fluid retention while enhancing reductions in albuminuria
medications.81–83 Patients with resistant hypertension who and blood pressure.76,84 When initiated, ERAs also induce a
are either intolerant of MRAs or for whom MRAs are modest, reversible decline in eGFR (attributable to eerent
contraindicated could be candidates for this therapy arteriolar vasodilation).76 Monitoring for anaemia is
(table 2).7 Given its teratogenic potential, aprocitentan is recommended, as mild reductions in haemoglobin are
PRECISION study⁸⁵ (phase 3), n=730 Dose-response study⁸⁴ (phase 2), n=490
Patient Patients with resistant hypertension despite three or more antihypertensive Patients with grade 1 to 2 hypertension; unattended seated diastolic blood pressure of
population medications; unattended seated systolic blood pressure of ≥140 mm Hg ≥90 mm Hg to <110 mm Hg after 4–6 weeks placebo run-in period
despite at least 4 weeks of treatment with a triple combination in a single
pill continued throughout the trial*
Intervention Aprocitentan 12·5 mg and 25 mg once daily vs placebo Aprocitentan 5 mg, 10 mg, 25 mg, or 50 mg once daily vs placebo and vs active comparator
(lisinopril 20 mg once daily)
Trial duration 48 weeks including 4-week double-blind phase, 32-week single-blind active 8 weeks
treatment phase, and 12-week randomised withdrawal phase
Primary Unattended office systolic blood pressure decrease at 4 weeks: −15·3 mm Hg Unattended office diastolic blood pressure decrease at 8 weeks: −6·3 mm Hg with aprocitentan
endpoint with aprocitentan 12·5 mg, −15·2 mm Hg with aprocitentan 25 mg, and 5 mg, −9·9 mm Hg with aprocitentan 10 mg, −12·0 mm Hg with aprocitentan 25 mg,
−11·5 mm Hg with placebo; difference vs placebo: −3·8 mm Hg (97·5% CI −10·0 mm Hg with aprocitentan 50 mg, −8·4 mm Hg with lisinopril 20 mg, and −4·9 mm Hg
−6·8 to −0·8) with aprocitentan 12·5 mg, and −3·7 mm Hg (97·5% CI with placebo; difference vs placebo: –1·31 mm Hg (–5·10 to 2·49) with aprocitentan 5 mg,
−6·2 to −2·1) with aprocitentan 25 mg −4·93 mm Hg (–8·68 to –1·17) with aprocitentan 10 mg, −6·99 mm Hg (–10·80 to –3·19) with
aprocitentan 25 mg, −4·95 mm Hg (–8·75 to –1·15) with aprocitentan 50 mg, and −3·81 mm Hg
(–7·26 to –0·37) with lisinopril 20 mg
Additional Change in 24 h ambulatory systolic blood pressure at 4 weeks (difference Unattended office systolic blood pressure decrease at 8 weeks: –10·3 mm Hg with aprocitentan
endpoints† vs placebo): –4·2 mm Hg (–6·2 to –2·1) with aprocitentan 12·5 mg, and 5 mg, –15·0 mm Hg with aprocitentan 10 mg, –18·5 mm Hg with aprocitentan 25 mg,
–5·9 mm Hg (–7·9 to –3·8) with aprocitentan 25 mg; changes in office –15·1 mm Hg with aprocitentan 50 mg, –12·8 mm Hg with lisinopril 20 mg, and –7·7 mm Hg
systolic blood pressure after 4 weeks in the placebo-controlled randomised with placebo; difference vs placebo: –2·45 mm Hg (–8·44 to 3·54) with aprocitentan 5 mg,
withdrawal phase: 5·8 mm Hg (3·7 to 7·9) for placebo vs aprocitentan 25 mg –7·05 mm Hg (–12·98 to –1·12) with aprocitentan 10 mg, –9·90 mm Hg (–15·92 to –3·88) with
aprocitentan 25 mg, –7·58 mm Hg (–13·58 to –1·59) with aprocitentan 50 mg, and –4·84 mm Hg
(–10·49 to 0·82) with lisinopril 20 mg; change in 24 h ambulatory systolic blood pressure at
8 weeks‡ (difference vs placebo): 0·87 mm Hg (–3·58 to 5·32) with aprocitentan 5 mg,
–3·99 mm Hg (–8·49 to 0·52) with aprocitentan 10 mg, –4·83 mm Hg (–9·33 to –0·33) with
aprocitentan 25 mg, –3·67 mm Hg (–8·08 to 0·73) with aprocitentan 50 mg, and –3·43 mm Hg
(–8·30 to 1·44) with lisinopril 20 mg
Key safety Peripheral oedema: 9% of patients who received aprocitentan 12·5 mg and Mild-to-moderate peripheral oedema in four patients (mainly at higher doses); dose-related
observations 18% in those who received aprocitentan 25 mg vs 2% in those who received decreases in haemoglobin, and increase in estimated plasma volume; eGFR changes: not
placebo; hospitalisation for heart failure: ten patients who received reported; no significant weight changes; no hepatotoxicity
aprocitentan and one who received placebo; eGFR changes at week 4:
approximately −1·0 mL/min per 1·73 m² with aprocitentan 12·5 mg,
approximately −2·0–3·0 mL/min per 1·73 m² with aprocitentan 25 mg,
and approximately −0·5 mL/min per 1·73 m² with placebo; no hepatotoxicity
Changes in blood pressure and eGFR are expressed as means, and differences vs placebo are expressed as mean (95% CI), unless otherwise stated. eGFR=estimated glomerular filtration rate. *The triple
combination in a single pill included hydrochlorothiazide, valsartan, and amlodipine. †Responder rates and use of rescue antihypertensive medications have not been reported. ‡In a subset of 281 patients.
Table 4: Blood pressure-lowering effects and key safety issues with aprocitentan in phase 2 and 3 trials in hypertension
10 www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1
Therapeutics
also common, reflecting a combination of haemodilution, given alone.90,91 Despite the ecacy of sacubitril–valsartan
diminished endothelin-1-mediated erythropoiesis, and at lowering blood pressure, subsequent development and
possibly increased hepcidin levels.76 Hepatotoxicity, licensing of this drug primarily focused on patients with
prominent with first-generation agents, is uncommon heart failure.92 A recent systematic review showed that
with newer ERAs, although liver function monitoring sacubitril–valsartan (200 mg or 400 mg orally) is more
remains advisable. eective than a conventional ARB or ACE inhibitor at
lowering blood pressure when combined with a thiazide
Natriuretic peptide system and cyclic guanosine and a calcium channel blocker in patients with resistant
monophosphate signalling-targeted therapies hypertension;93 this superiority was also confirmed in
The natriuretic peptides—atrial natriuretic peptide and patients of Black African ancestry.94 Furthermore, after
B-type natriuretic peptide—are released from the atria 52 weeks of treatment, one trial95 found that sacubitril–
and ventricles, respectively, in response to wall stretch due valsartan reduced diuse interstitial fibrosis and
to volume, pressure overload, or both. Their biological favourably decreased left ventricular mass in hypertensive
action to promote natriuresis, diuresis, vasodilation, patients with left ventricular hypertrophy, compared with
suppression of renin, aldosterone, and the sympathetic valsartan alone, when both regimens were titrated and
nervous system, as well as antifibrotic, anti-inflammatory, combined with other antihypertensives to reach a systolic
and antihypertrophic eects, are principally mediated via blood pressure target of less than 140 mm Hg. Sacubitril–
binding to the atrial natriuretic peptide receptor 1.85 valsartan is not approved for the treatment of
The challenge is that natriuretic peptides have a short hypertension in Europe and the USA.
half-life of only minutes in the systemic circulation, due
to rapid degradation by enzymes such as neprilysin and Direct natriuretic peptide system activators
clearance by the natriuretic peptide clearance receptor. Intravenous recombinant natriuretic peptides are
Upon binding to the atrial natriuretic peptide receptor 1, approved for decompensated heart failure, but their
atrial natriuretic peptide and B-type natriuretic peptide short half-life and route of administration limits broader
activate cyclic guanosine monophosphate signalling, use.85 Modified forms of the atrial natriuretic peptide,
which mediates the aforementioned action of the designed as ANP mimetics, are engineered to be more
natriuretic peptides.86 Strategies have been developed to resistant to enzymatic degradation and renal clearance. A
exploit the potential of the natriuretic peptide system to proof-of-concept study96 confirmed that a single
treat hypertension, such as augmenting the natural subcutaneous injection lowered blood pressure,
natriuretic peptide system by inhibiting the degradation increased cyclic guanosine monop hosphate
of atrial natriuretic peptide and B-type natriuretic concentrations, and was not associated with serious
peptide, or by direct activation of the atrial natriuretic adverse events, but the plasma half-life of ANP was only
peptide receptor 1. extended to around 1 h and the blood pressure eect
waned substantially by 24 h.96,97 The short duration of
Augmenting the natriuretic peptide system: neprilysin action and the need for daily subcutaneous injection
inhibitors would be challenging for its adoption as a long-term
Inhibition of neprilysin to augment the circulating levels treatment.
of atrial natriuretic peptide and B-type natriuretic
peptide, and prolong their half-life, has the potential to Conclusions
substantially lower blood pressure, especially when There has been renewed interest in the development of
combined with renin–angiotensin system inhibition. new antihypertensive medications; however, how these
The blood pressure-lowering potential of dual inhibition treatments will be integrated with established, low-cost
of both ACE and neprilysin was originally confirmed generic antihypertensive drugs remains uncertain.
with omapatrilat, but its developm ent was discontinued Moreover, combining these novel agents into single-pill
because it was associated with a higher risk of angio- combination products would also be challenging given
oedema than ACE inhibition alone,87 probably due to regulatory requirements for outcomes-based trials and the
concomitant inhibition of neprilysin, ACE, and poor uptake of existing single-pill products, despite their
aminopeptidase P, all of which participate in the increasing endorsement in clinical guidelines worldwide.
breakdown of bradykinin.88 Subsequently, a sacubitril– Furthermore, in low-income and middle-income countries,
valsartan combination was developed, which combined where the availability, accessibility, and aordability of care
the neprilysin inhibitor sacubitril with the ARB valsartan and therapies remain constrained, demonstration of cost-
in a single oral tablet.89 When used at higher doses than eectiveness will be essential to establish the feasibility
in heart failure (ie, 400 mg/day), this dual-acting and the potential global eect of these new therapeutic
combination therapy was shown to be eective at approaches. Thus, it could be argued that the focus should
lowering blood pressure in patients with mild-to- be on developing more eective systems of care to enhance
moderate hypertension when compared with each of its adherence to existing low-cost treatments. However, this
components given alone89 and versus the ARB olmesartan approach has proved challenging, and despite multiple
www.thelancet.com Published online February 10, 2025 https://doi.org/10.1016/S0140-6736(25)02064-1 11
Therapeutics
iterations of guidelines and various models of care, overall and revision of the manuscript, and had final responsibility for the
global blood pressure control rates have not improved decision to submit for publication.
substantially. Moreover, recent advances in other medical Declaration of interests
fields challenge the assumption that we already have all of MA reports institutional grants from Novartis, Recor Medical,
the treatments we need. The advent of SGLT2 inhibitors AstraZeneca, and Sonivie; consulting fees from Novartis, Recor Medical,
AstraZeneca, Alnylam, Medtronic, and Sonivie; honoraria for lectures
and GLP-1 receptor agonists has transformed the
from Servier, NovoNordisk, Boehringer Ingelheim, and Alnylam; and
management of patients with high cardiovascular risk, travel support from Novartis. KRT reports investigator-initiated grant
chronic kidney disease, diabetes, obesity, and heart support from Travere, Bayer, Benaroya Research Institute, and the
Doris Duke Charitable Foundation; consultancy fees from Boehringer
failure—conditions once considered adequately treated
Ingelheim, Eli Lilly, Novo Nordisk, Roche–Genentech, AstraZeneca, and
with existing therapies. These developments highlight the
ProKidney; speaker fees from Novo Nordisk, Bayer, and Boehringer
potential for innovative antihypertensive drugs to improve Ingelheim; travel support from Bayer and Novo Nordisk; is chair of data
standards of care and address residual disease risk, even in safety monitoring boards for the National Institute of Diabetes and
Digestive and Kidney Disease and for the George Clinical Institute; is a
a therapeutic landscape dominated by inexpensive generic
member of the data safety monitoring board for AstraZeneca; is chair for
drugs.
the Diabetic Kidney Disease Collaborative for the American Society of
Unlike many drug developments in medicine, the new Nephrology and for the Kidney Week 2025 Program Committee; and is a
antihypertensive therapies we have discussed have the member of the American Heart Association/American College of
Cardiology Cardiovascular–Kidney–Metabolic Guideline Committee.
potential to transform hypertension management. RNA
JMB reports consulting fees from AstraZeneca, Bayer, and Recordati
silencing therapies oer the potential to deliver the first Rare Diseases; and funding from the American Heart Association
always-on blood pressure-lowering treatment, lasting for (grant 21CDA852429) and US National Institutes of Health/National
at least 6 months after a single subcutaneous injection, Heart, Lung, and Blood Institute (grant K23HL159279). DLP reports
consulting fees, honoraria, participation on an advisory board, and travel
overcoming the substantial problem of low treatment
support from Novo Nordisk. KK reports research grants from Otsuka
adherence. How this therapy would aect patient Pharmaceutical, Daiichi Sankyo, Sumitomo Pharma, and Nippon
outcomes is unknown but, at a population level, even a Boehringer Ingelheim; consulting fees from Sanwa Kagaku Kenkyusho;
modest sustained blood pressure reduction could prevent honoraria from Otsuka Pharmaceuticals, Daiichi Sankyo, Novartis
Pharma, and Viatris; and participation on advisory boards for Daiichi
thousands of cardiovascular events per year.98 Furthermore,
Sankyo and Novartis Pharma. BW is Chief Scientific and Medical Ocer
better targeting of disease pathophysiology with novel of the British Heart Foundation; reports consulting fees from Novartis,
treatments such as ASIs has the potential to transform the AstraZeneca, Alnylam, and Antlia; and reports honoraria from
treatment of blood pressure in the many millions of Medtronic.
people with (often unrecognised) aldosterone References
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