Antihypertensives are a class of drugs that are used to treat hypertension (high blood pressure).[1] Antihypertensive therapy seeks to prevent the complications of high blood pressure, such as stroke and myocardial infarction. Evidence suggests that reduction of the blood pressure by 5 mmHg can decrease the risk of stroke by 34%, of ischaemic heart disease by 21%, and reduce the likelihood of dementia, heart failure, and mortality from cardiovascular disease.[2] There are many classes of antihypertensives, which lower blood pressure by different means. Among the most important and most widely used drugs are thiazide diuretics, calcium channel blockers, ACE inhibitors, angiotensin II receptor antagonists (ARBs), and beta blockers.
Which type of medication to use initially for hypertension has been the subject of several large studies and resulting national guidelines. The fundamental goal of treatment should be the prevention of the important endpoints of hypertension, such as heart attack, stroke and heart failure. Patient age, associated clinical conditions and end-organ damage also play a part in determining dosage and type of medication administered.[3] The several classes of antihypertensives differ in side effect profiles, ability to prevent endpoints, and cost. The choice of more expensive agents, where cheaper ones would be equally effective, may have negative impacts on national healthcare budgets.[4] As of 2009, the best available evidence favors the thiazide diuretics as the first-line treatment of choice for high blood pressure when drugs are necessary.[5] Although clinical evidence shows calcium channel blockers and thiazide-type diuretics are preferred first-line treatments for most people (from both efficacy and cost points of view), an ACE inhibitor is recommended by NICE in the UK for those under 55 years old.[6]
Contents
- 1 Diuretics
- 2 Calcium channel blockers
- 3 ACE inhibitors
- 4 Angiotensin II receptor antagonists
- 5 Adrenergic receptor antagonists
- 6 Vasodilators
- 7 Benzodiazepines
- 8 Renin Inhibitors
- 9 Aldosterone receptor antagonists
- 10 Alpha-2 adrenergic receptor agonists
- 11 Endothelin receptor blockers
- 12 Future treatment options
- 12.1 Blood pressure vaccines
- 13 Choice of initial medication
- 13.1 Patient Factors Affecting Antihypertensive Drug Choice
- 14 See also
- 15 References
Diuretics
Hydrochlorothiazide, a popular thiazide diuretic
Diuretics help the kidneys eliminate excess salt and water from the body's tissues and blood.
- Loop diuretics:
- bumetanide
- ethacrynic acid
- furosemide
- torsemide
- Thiazide diuretics:
- epitizide
- hydrochlorothiazide and chlorothiazide
- bendroflumethiazide
- Thiazide-like diuretics:
- indapamide
- chlorthalidone
- metolazone
- Potassium-sparing diuretics:
- amiloride
- triamterene
- spironolactone
Only the thiazide and thiazide-like diuretics have good evidence of beneficial effects on important endpoints of hypertension, and hence, should usually be the first choice when selecting a diuretic to treat hypertension. The reason why thiazide-type diuretics are better than the others is (at least in part) thought to be because of their vasodilating properties.[citation needed] Although the diuretic effect of thiazides may be apparent shortly after administration, it takes longer (weeks of treatment) for the full anti-hypertensive effect to develop.[citation needed]
In the United States, the JNC8 (Eighth Joint National Committee on the Prevention, Detection, Evaluation, and Treatment of High Blood Pressure) recommends thiazide-type diuretics to be one of the first-line drug treatments for hypertension, either as monotherapy or in combination with calcium channel blockers, ACE inhibitors, or angiotensin II receptor antagonists.[7] Despite thiazides being cheap and effective, they are not prescribed as often as some newer drugs. This is because they have been associated with increased risk of new-onset diabetes and as such are recommended for use in patients over 65 where the risk of new-onset diabetes is outweighed by the benefits of controlling systolic blood pressure.[8] Another theory is that they are off-patent and thus rarely promoted by the drug industry.[9]
Calcium channel blockers
Calcium channel blockers block the entry of calcium into muscle cells in artery walls.
- dihydropyridines:
- amlodipine
- cilnidipine
- felodipine
- isradipine
- lercanidipine
- levamlodipine
- nicardipine
- nifedipine
- nimodipine
- nitrendipine
- non-dihydropyridines:
JNC8 recommends calcium channel blockers to be a first-line treatment either as monotherapy or in combination with thiazide-type diuretics, ACE inhibitors, or angiotensin II receptor antagonists for all patients regardless of age or race.[7]
ACE inhibitors
Captopril, the prototypical ACE inhibitor
ACE inhibitors inhibit the activity of angiotensin-converting enzyme (ACE), an enzyme responsible for the conversion of angiotensin I into angiotensin II, a potent vasoconstrictor.
- captopril
- enalapril
- fosinopril
- lisinopril
- perindopril
- quinapril
- ramipril
- trandolapril
- benazepril
A systematic review of 63 trials with over 35,000 participants indicated ACE inhibitors significantly reduced doubling of serum creatinine levels compared to other drugs (ARBs, α blockers, β blockers, etc.), and the authors suggested this as a first line of defense.[10] The AASK trial showed that ACE inhibitors are more effective at slowing down the decline of renal function compared to calcium channel blockers and beta blockers.[11] As such, ACE inhibitors should be the drug treatment of choice for patients with chronic kidney disease regardless of race or diabetic status.[7]
However, ACE inhibitors (and angiotensin II receptor antagonists) should not be a first-line treatment for black hypertensives without chronic kidney disease.[7] Results from the ALLHAT trial showed that thiazide-type diuretics and calcium channel blockers were both more effective as monotherapy in improving cardiovascular outcomes compared to ACE inhibitors for this subgroup.[12] Furthermore, ACE inhibitors were less effective in reducing blood pressure and had a 51% higher risk of stroke in black hypertensives when used as initial therapy compared to a calcium channel blocker.[13]
Angiotensin II receptor antagonists
Valsartan, an angiotensin II receptor antagonist
Angiotensin II receptor antagonists work by antagonizing the activation of angiotensin receptors.
- candesartan
- eprosartan
- irbesartan
- losartan
- olmesartan
- telmisartan
- valsartan
Whether angiotensin receptor blockers may or may not increase the risk of myocardial infarction (heart attack) was announced in BMJ[14] and was debated in 2006 in the medical journal of the American Heart Association.[15][16] To date[when?], there is no consensus on whether ARBs have a tendency to increase MI, but there is also no substantive evidence to indicate that ARBs are able to reduce MI.
In the VALUE trial, the angiotensin II receptor blocker valsartan produced a statistically significant 19% (p=0.02) relative increase in the prespecified secondary end point of myocardial infarction (fatal and non-fatal) compared with amlodipine.[17]
The CHARM-alternative trial showed a significant +52% (p=0.025) increase in myocardial infarction with candesartan (versus placebo) despite a reduction in blood pressure.[18]
Indeed, as a consequence of AT1 blockade, ARBs increase Angiotensin II levels several-fold above baseline by uncoupling a negative-feedback loop. Increased levels of circulating Angiotensin II result in unopposed stimulation of the AT2 receptors, which are, in addition upregulated. Unfortunately, recent data suggest that AT2 receptor stimulation may be less beneficial than previously proposed and may even be harmful under certain circumstances through mediation of growth promotion, fibrosis, and hypertrophy, as well as proatherogenic and proinflammatory effects.[19][20][21]
Adrenergic receptor antagonists
Propranolol, the first beta-blocker to be successfully developed
- Beta blockers
- atenolol
- metoprolol
- nadolol
- nebivolol
- oxprenolol
- pindolol
- propranolol
- timolol
- Alpha blockers:
- doxazosin
- phentolamine
- indoramin
- phenoxybenzamine
- prazosin
- terazosin
- tolazoline
- Mixed Alpha + Beta blockers:
- bucindolol
- carvedilol
- labetalol
Although beta blockers lower blood pressure, they do not have a positive benefit on endpoints as some other antihypertensives.[22] In particular, beta-blockers are no longer recommended as first-line treatment due to relative adverse risk of stroke and new-onset of type 2 diabetes when compared to other medications,[3] while certain specific beta-blockers such as atenolol appear to be less useful in overall treatment of hypertension than several other agents.[23] A systematic review of 63 trials with over 35,000 participants indicated β-blockers increased the risk of mortality, compared to other antihypertensive therapies.[10] They do, however, have an important role in the prevention of heart attacks in people who have already had a heart attack.[24] In the United Kingdom, the June 2006 "Hypertension: Management of Hypertension in Adults in Primary Care"[25] guideline of the National Institute for Health and Clinical Excellence, downgraded the role of beta-blockers due to their risk of provoking type 2 diabetes.[26]
Despite lowering blood pressure, alpha blockers have significantly poorer endpoint outcomes than other antihypertensives, and are no longer recommended as a first-line choice in the treatment of hypertension.[27] However, they may be useful for some men with symptoms of prostate disease.
Vasodilators
Vasodilators act directly on the smooth muscle of arteries to relax their walls so blood can move more easily through them; they are only used in hypertensive emergencies or when other drugs have failed, and even so are rarely given alone.
Sodium nitroprusside, a very potent, short-acting vasodilator, is most commonly used for the quick, temporary reduction of blood pressure in emergencies (such as malignant hypertension or aortic dissection).[28][29] Hydralazine and its derivatives are also used in the treatment of severe hypertension, although they should be avoided in emergencies.[29] They are no longer indicated as first-line therapy for high blood pressure due to side effects and safety concerns, but hydralazine remains a drug of choice in gestational hypertension.[28]
Benzodiazepines
Although controversial over this off-label purpose, benzodiazepines may play a role in lowering blood pressure. They work as an agonist of the GABA-a receptors in the brain, thus slowing down neurotransmission and dilating blood vessels. GABA is an abbreviation for gamma-aminobutyric acid. It is an inhibitory neurotransmitter among others (glycine, adenosine, etc.) GABA-a receptors are ion channels that are the primary target for benzodiazepines. When an agonist binds to this receptor site, the protein channel opens, allowing negative chloride ions entering the channel and penetrating the voltage-gated ion site. Thus, giving negative feedback in neurotransmission and easing stress, anxiety and tension in patients that can be associated with elevated blood pressure.[30] In addition to GABA, benzodiazepines inhibit the re-uptake of a nucleoside chemical called Adenosine, which serves as an inhibitory chemical mentioned above. It also serves as a coronary vasodilator, allowing the cardiac muscle to relax and dilating cardiac arteries.[31]
Renin Inhibitors
Renin comes one level higher than angiotensin converting enzyme (ACE) in the renin-angiotensin system. Inhibitors of renin can therefore effectively reduce hyptertension. Aliskiren (developed by Novartis) is a renin inhibitor which has been approved by the U.S. FDA for the treatment of hypertension.[32]
Aldosterone receptor antagonists
Aldosterone receptor antagonists:
- eplerenone
- spironolactone
Aldosterone receptor antagonists are not recommended as first-line agents for blood pressure,[33] but spironolactone and eplerenone are both used in the treatment of heart failure.
Alpha-2 adrenergic receptor agonists
Central alpha agonists lower blood pressure by stimulating alpha-receptors in the brain which open peripheral arteries easing blood flow. These alpha 2 receptors are known as autoreceptors which provide a negative feedback in neurotransmission (in this case, the vasoconstriction effects of adrenaline). Central alpha agonists, such as clonidine, are usually prescribed when all other anti-hypertensive medications have failed. For treating hypertension, these drugs are usually administered in combination with a diuretic.
- clonidine
- guanabenz
- guanfacine
- methyldopa
- moxonidine
Adverse effects of this class of drugs include sedation, drying of the nasal mucosa and rebound hypertension.
Some indirect anti-adrenergics are rarely used in treatment-resistant hypertension:
- guanethidine - replaces norepinephrine in vesicles, decreasing its tonic release
- mecamylamine - antinicotinic and ganglion blocker
- reserpine - indirect via irreversible VMAT inhibition
For the most resistant and severe disease, oral minoxidil (Loniten) in combination with diuretic and β-blocker or other sympathetic nervous system suppressant may be used.
Endothelin receptor blockers
Bosentan belongs to a new class of drug and works by blocking the receptors of the hormone endothelin. It is specifically indicated only for the treatment of pulmonary artery hypertension in patients with moderate to severe heart failure.
Future treatment options
Blood pressure vaccines
Blood pressure vaccinations are being trialed and may become a treatment option for high blood pressure in the future. CYT006-AngQb was only moderately successful in studies, but similar vaccines are being investigated.[34]
Choice of initial medication
For mild blood pressure elevation, consensus guidelines call for medically supervised lifestyle changes and observation before recommending initiation of drug therapy. However, according to the American Hypertension Association, evidence of sustained damage to the body may be present even prior to observed elevation of blood pressure. Therefore the use of hypertensive medications may be started in individuals with apparent normal blood pressures but who show evidence of hypertension related nephropathy, proteinuria, atherosclerotic vascular disease, as well as other evidence of hypertension related organ damage.
If lifestyle changes are ineffective, then drug therapy is initiated, often requiring more than one agent to effectively lower hypertension. Which type of many medications should be used initially for hypertension has been the subject of several large studies and various national guidelines. Considerations include factors such as age, race, and other medical conditions.[33] In the United States, JNC8 (2014) recommends any drug from one of the four following classes to be a good choice as either initial therapy or as an add-on treatment: thiazide-type diuretics, calcium channel blockers, ACE inhibitors, or angiotensin II receptor antagonists.[7]
The largest study, Antihypertensive and Lipid-Lowering Treatment to Prevent Heart Attack Trial (ALLHAT) in 2002, concluded that thiazide-type diuretics are better and cheaper than other major classes of drugs at preventing cardiovascular disease, and should be preferred as the starting drug. ALLHAT used the thiazide diuretic chlorthalidone.[12] (ALLHAT showed that doxazosin, an alpha-adrenergic receptor blocker, had a higher incidence of heart failure events, and the doxazosin arm of the study was stopped.)
A subsequent smaller study (ANBP2) did not show the slight advantages in thiazide diuretic outcomes observed in the ALLHAT study, and actually showed slightly better outcomes for ACE-inhibitors in older white male patients.[35]
Thiazide diuretics are effective, recommended as the best first-line drug for hypertension by many experts,[citation needed] and are much more affordable than other therapies, yet they are not prescribed as often as some newer drugs. Hydrochlorothiazide is perhaps the safest and most inexpensive agent commonly used in this class and is very frequently combined with other agents in a single pill. Doses in excess of 25 milligrams per day of this agent incur an unacceptable risk of low potassium or Hypokalemia. Patients with an exaggerated hypokalemic response to a low dose of a thiazide diuretic should be suspected to have Hyperaldosteronism, a common cause of secondary hypertension.
Other drugs have a role in treating hypertension. Adverse effects of thiazide diuretics include hypercholesterolemia, and impaired glucose tolerance with increased risk of developing Diabetes mellitus type 2. The thiazide diuretics also deplete circulating potassium unless combined with a potassium-sparing diuretic or supplemental potassium. Some authors have challenged thiazides as first line treatment.[36][37][38] However as the Merck Manual of Geriatrics notes, "thiazide-type diuretics are especially safe and effective in the elderly."[39]
Current UK guidelines suggest starting patients over the age of 55 years and all those of African/Afrocaribbean ethnicity firstly on calcium channel blockers or thiazide diuretics, whilst younger patients of other ethnic groups should be started on ACE-inhibitors. Subsequently if dual therapy is required to use ACE-inhibitor in combination with either a calcium channel blocker or a (thiazide) diuretic. Triple therapy is then of all three groups and should the need arise then to add in a fourth agent, to consider either a further diuretic (e.g. spironolactone or furosemide), an alpha-blocker or a beta-blocker.[40] Prior to the demotion of beta-blockers as first line agents, the UK sequence of combination therapy used the first letter of the drug classes and was known as the "ABCD rule".[40][41]
Patient Factors Affecting Antihypertensive Drug Choice
The choice between the drugs is to a large degree determined by the characteristics of the patient being prescribed for, the drugs' side-effects, and cost. Most drugs have other uses; sometimes the presence of other symptoms can warrant the use of one particular antihypertensive. Examples include:
- Age can affect choice of medications. Current UK guidelines suggest starting patients over the age of 55 years first on calcium channel blockers or thiazide diuretics.
- Anxiety may be improved with the use of beta blockers.
- Asthmatics have been reported to have worsening symptoms when using beta blockers.
- Benign prostatic hyperplasia may be improved with the use of an alpha blocker.
- Chronic kidney disease. ACE inhibitors or ARBs should be included in the treatment plan to improve kidney outcomes regardless of race or diabetic status.[7][11]
- Diabetes. The ace inhibitors and angiotensin receptor blockers have been shown to prevent the renal and retinal complications of diabetes mellitus.
- Gout may be worsened by diuretics, while losartan reduces serum urate.[42]
- Kidney stones may be improved with the use of thiazide-type diuretics [43]
- Heart block. β-blockers and nondihydropyridine calcium channel blockers should not be used in patients with heart block greater than first degree. JNC8 does not recommend β-blockers as initial therapy for hypertension [44]
- Heart failure may be worsened with nondihydropyridine calcium channel blockers, the alpha blocker doxazosin, and the alpha-2 agonists moxonidine and clonidine. Whereas β-blockers, diuretics, ACE inhibitors, angiotensin receptor blockers, and aldosterone receptor antagonists have been shown to improve outcome.[45]
- Pregnancy. Although α-methyldopa is generally regarded as a first-line agent, labetalol and metoprolol are also acceptable. Atenolol has been associated with intrauterine growth retardation, as well as decreased placental growth and weight when prescribed during pregnancy. Ace inhibitors and angiotensin II receptor blockers (ARBs)are contraindicated in women who are or who intend to become pregnant.[33]
- Race. JNC8 guidelines particularly points out that when used as monotherapy, thiazide diuretics and calcium channel blockers have been found to be more effective for reducing blood pressure in black hypertensives than β-blockers, ACE inhibitors, or ARBs.[7]
- Tremor may warrant the use of beta blockers.
The JNC8 guidelines indicate reasons to choose one drug over the others for certain individual patients.[7]
See also
- Prehypertension
- Pulse pressure
References
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Sympatholytic (and closely related) antihypertensives (C02)
|
|
Sympatholytics
(antagonize α-adrenergic
vasoconstriction) |
Central |
α2 agonist |
- Clonidine
- Guanabenz
- Guanfacine
- Methyldopa#
- Tiamenidine‡
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Adrenergic release inhibitors |
- Bethanidine
- Bretylium
- Debrisoquine
- Guanadrel
- Guanazodine
- Guanethidine
- Guanoclor
- Guanazodine
- Guanoxabenz
- Guanoxan
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|
Imidazoline receptor agonist |
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Ganglion-blocking/nicotinic antagonist |
- Hexamethonium‡
- Mecamylamine
- Pentolinium
- Trimethaphan
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Peripheral |
Indirect |
MAOI |
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Adrenergic uptake inhibitor |
- Bietaserpine
- Deserpidine
- Methoserpidine
- Rescinnamine
- Reserpine
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Tyrosine hydroxylase inhibitor |
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Direct |
α1 blockers |
- Prazosin
- Indoramin
- Trimazosin
- Doxazosin
- Urapidil
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Non-selective α blocker |
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Other antagonists |
Serotonin antagonist |
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Endothelin antagonist (for PH) |
- dual (Bosentan, Macitentan)
- selective (Ambrisentan, Sitaxentan)
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- #WHO-EM
- ‡Withdrawn from market
- Clinical trials:
- †Phase III
- §Never to phase III
Index of the circulatory system
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Description |
- Anatomy
- Arteries
- head and neck
- arms
- chest
- abdomen
- legs
- Veins
- head and neck
- arms
- chest
- abdomen and pelvis
- legs
- Development
- Cells
- Physiology
|
|
Disease |
- Congenital
- Neoplasms and cancer
- Lymphatic vessels
- Injury
- Vasculitis
- Other
- Symptoms and signs
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|
Treatment |
- Procedures
- Drugs
- beta blockers
- channel blockers
- diuretics
- nonsympatholytic vasodilatory antihypertensives
- peripheral vasodilators
- renin–angiotensin system
- sympatholytic antihypertensives
- vasoprotectives
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|
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Antihypertensives: diuretics (C03)
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Sulfonamides
(and etacrynic acid) |
CA inhibitors (at PT) |
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Loop (Na-K-Cl at AL) |
- Furosemide#
- Bumetanide
- Etacrynic acid
- Etozoline
- Muzolimine
- Piretanide
- Tienilic acid
- Torasemide
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Thiazides (Na-Cl at DCT,
Calcium-sparing) |
- Altizide
- Bendroflumethiazide
- Chlorothiazide
- Cyclopenthiazide
- Cyclothiazide
- Epitizide
- Hydrochlorothiazide#
- Hydroflumethiazide
- Mebutizide
- Methyclothiazide
- Polythiazide
- Trichlormethiazide
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|
Thiazide-likes (primarily DCT) |
- Quinethazone
- Clopamide
- Chlortalidone
- Mefruside
- Clofenamide
- Metolazone
- Meticrane
- Xipamide
- Indapamide
- Clorexolone
- Fenquizone
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|
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Potassium-sparing (at CD) |
ESC blockers |
- Amiloride#
- Triamterene
- Benzamil
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|
Aldosterone antagonists |
- Spirolactones: Spironolactone#
- Eplerenone
- Potassium canrenoate
- Canrenone
- Non-steroidal: Finerenone
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Osmotic diuretics (PT, DL) |
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|
Vasopressin receptor inhibitors
(DCT and CD) |
- Vaptans: Conivaptan
- Mozavaptan
- Satavaptan
- Tolvaptan
- Others: Demeclocycline
- Lithium carbonate
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Other |
- ethanol, isopropanol, 2M2B
- mercurial diuretic (Mersalyl, Meralluride)
- Theobromine
- Cicletanine
|
|
- #WHO-EM
- ‡Withdrawn from market
- Clinical trials:
- †Phase III
- §Never to phase III
Index of the circulatory system
|
|
Description |
- Anatomy
- Arteries
- head and neck
- arms
- chest
- abdomen
- legs
- Veins
- head and neck
- arms
- chest
- abdomen and pelvis
- legs
- Development
- Cells
- Physiology
|
|
Disease |
- Congenital
- Neoplasms and cancer
- Lymphatic vessels
- Injury
- Vasculitis
- Other
- Symptoms and signs
|
|
Treatment |
- Procedures
- Drugs
- beta blockers
- channel blockers
- diuretics
- nonsympatholytic vasodilatory antihypertensives
- peripheral vasodilators
- renin–angiotensin system
- sympatholytic antihypertensives
- vasoprotectives
|
|
|
Antihypertensives: agents acting on the renin–angiotensin system (C09)
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|
ACE inhibitors
("-pril") |
- Sulfhydryl-containing: Captopril
- Rentiapril
- Zofenopril
- Dicarboxylate-containing: Enalapril#
- Benazepril
- Cilazapril
- Delapril
- Imidapril
- Lisinopril (+HCT)
- Moexipril
- Perindopril
- Quinapril (+HCT)
- Ramipril
- Spirapril
- Temocapril
- Trandolapril
- Phosphonate-containing: Fosinopril (+HCT)
- Other/ungrouped: Alacepril
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|
AIIRAs/
("-sartan") |
- Azilsartan
- Candesartan
- Eprosartan
- Fimasartan
- Irbesartan
- Losartan (+HCT)
- Olmesartan (+amlodipine)
- Tasosartan§
- Telmisartan (+HCT)
- Valsartan (+HCT, +amlodipine, +sacubitril)
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|
Renin inhibitors/
("-kiren") |
- Aliskiren (+amlodipine, +amlodipine and HCT)
- Remikiren§
|
|
- #WHO-EM
- ‡Withdrawn from market
- Clinical trials:
- †Phase III
- §Never to phase III
Index of the circulatory system
|
|
Description |
- Anatomy
- Arteries
- head and neck
- arms
- chest
- abdomen
- legs
- Veins
- head and neck
- arms
- chest
- abdomen and pelvis
- legs
- Development
- Cells
- Physiology
|
|
Disease |
- Congenital
- Neoplasms and cancer
- Lymphatic vessels
- Injury
- Vasculitis
- Other
- Symptoms and signs
|
|
Treatment |
- Procedures
- Drugs
- beta blockers
- channel blockers
- diuretics
- nonsympatholytic vasodilatory antihypertensives
- peripheral vasodilators
- renin–angiotensin system
- sympatholytic antihypertensives
- vasoprotectives
|
|
|