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ACE inhibitor

December 18, 2023

"ACEI" redirects here. For other uses, see acei (disambiguation).
Not to be confused with Acetylcholinesterase inhibitor.

Angiotensin-converting-enzyme inhibitors (ACE inhibitors) are a class of medication used primarily for the treatment of high blood pressure and heart failure.[1][2] This class of medicine works by causing relaxation of blood vessels as well as a decrease in blood volume, which leads to lower blood pressure and decreased oxygen demand from the heart.

Angiotensin-converting-enzyme inhibitor
Drug class
Captopril, the first synthetic ACE inhibitor
Class identifiers
UseHypertension
ATC codeC09A
Biological targetAngiotensin-converting enzyme
Clinical data
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Consumer ReportsBest Buy Drugs
WebMDMedicineNet  RxList
External links
MeSHD000806
Legal status
In Wikidata

ACE inhibitors inhibit the activity of angiotensin-converting enzyme, an important component of the renin–angiotensin system which converts angiotensin I to angiotensin II,[3] and hydrolyses bradykinin.[1] Therefore, ACE inhibitors decrease the formation of angiotensin II, a vasoconstrictor, and increase the level of bradykinin, a peptide vasodilator.[1][3] This combination is synergistic in lowering blood pressure.[1][3] As a result of inhibiting the ACE enzyme in the bradykinin system, the ACE inhibitor drugs allow for increased levels of bradykinin which would normally be degraded. Bradykinin produces prostaglandin. This mechanism can explain the two most common side effects seen with ACE Inhibitors: angioedema and cough.

Frequently prescribed ACE inhibitors include benazepril, zofenopril, perindopril, trandolapril, captopril, enalapril, lisinopril, and ramipril.

Medical use edit

ACE inhibitors were initially approved for the treatment of hypertension and can be used alone or in combination with other anti-hypertensive medications. Later, they were found useful for other cardiovascular and kidney diseases[4] including:

In treating high blood pressure, ACE inhibitors are often the first drug choice, particularly when diabetes is present,[8] but age can lead to different choices and it is common to need more than one drug to obtain the desired improvement. There are fixed-dose combination drugs, such as ACE inhibitor and thiazide combinations. ACE inhibitors have also been used in chronic kidney failure and kidney involvement in systemic sclerosis (hardening of tissues, as scleroderma renal crisis). In those with stable coronary artery disease, but no heart failure, benefits are similar to other usual treatments.[9]

In 2012, there was a meta-analysis published in the BMJ that described the protective role of ACE inhibitors in reducing the risk of pneumonia when compared to angiotensin II receptor blocker (ARBs).[10] The authors found a decreased risk in patients with previous stroke (54% risk reduction), with heart failure (37% risk reduction), and of Asian descent (43% risk reduction vs 54% risk reduction in non-Asian population). However, no reduced pneumonia related mortality was observed.[11]

Other edit

ACE inhibitors may also be used to help decrease excessive water consumption in people with schizophrenia resulting in psychogenic polydipsia.[12][13] A double-blind, placebo-controlled trial showed that when used for this purpose, enalapril led to decreased consumption (determined by urine output and osmolality) in 60% of people;[14] the same effect has been demonstrated in other ACE inhibitors.[15]

Additionally ACE-I are commonly used after renal transplant to manage post-transplant erythrocytosis, a condition characterised by a persistently high hematocrit greater than 51% which often develops 8–24 months after successful transplantation,[16] as ACE-I have been shown to decrease erythropoietin production.[17]

Adverse effects edit

Common side effects include: low blood pressure, cough, hyperkalemia, headache, dizziness, fatigue, nausea, and kidney impairment.[18][19]

The main adverse effects of ACE inhibition can be understood from their pharmacological action. The other reported adverse effects are liver problems and effects on the fetus.[19] Kidney problems may occur with all ACE inhibitors that directly follows from their mechanism of action. Patients starting on an ACE inhibitor usually have a modest reduction in glomerular filtration rate (GFR).[20] However, the decrease may be significant in conditions of pre-existing decreased renal perfusions, such as renal artery stenosis, heart failure, polycystic kidney disease, or volume depletion. In these patients, the maintenance of GFR depends on angiotensin-II-dependent efferent vasomotor tone.[20] Therefore, renal function should be closely monitored over the first few days after initiation of treatment with ACE inhibitor in patients with decreased renal perfusion.[19] A moderate reduction in renal function, no greater than 30% rise in serum creatinine, that is stabilized after a week of treatment is deemed acceptable as part of the therapeutic effect, providing the residual renal function is sufficient.

Reduced GFR is especially a problem if the patient is concomitantly taking an NSAID and a diuretic.[21] When the three drugs are taken together, the risk of developing renal failure is significantly increased.[22]

High blood potassium is another possible complication of treatment with an ACE inhibitor due to its effect on aldosterone. Suppression of angiotensin II leads to a decrease in aldosterone levels. Since aldosterone is responsible for increasing the excretion of potassium, ACE inhibitors can cause retention of potassium. Some people, however, can continue to lose potassium while on an ACE inhibitor.[23] Hyperkalemia may decrease the velocity of impulse conduction in the nerves and muscles, including cardiac tissues. This leads to cardiac dysfunction and neuromuscular consequences, such as muscle weakness, paresthesia, nausea, diarrhea, and others. Close monitoring of potassium levels is required in patients receiving treatment with ACE inhibitors who are at risk of hyperkalemia.[19]

Another possible adverse effect specific for ACE inhibitors, but not for other RAAS blockers, is an increase in bradykinin level.[19]

A persistent dry cough is a relatively common adverse effect believed to be associated with the increases in bradykinin levels produced by ACE inhibitors, although the role of bradykinin in producing these symptoms has been disputed.[24] Many cases of cough in people on ACE inhibitors may not be from the medication itself, however.[25] People who experience this cough are often switched to angiotensin II receptor antagonists.

Some (0.7%)[21] develop angioedema due to increased bradykinin levels.[26] A genetic predisposition may exist.[27]

A severe rare allergic reaction can affect the bowel wall and secondarily cause abdominal pain.[28]

Blood edit

Hematologic effects, such as neutropenia, agranulocytosis and other blood dyscrasias, have occurred during therapy with ACE inhibitors, especially in people with additional risk factors.[29]

Pregnancy edit

In pregnant women, ACE inhibitors taken during all the trimesters have been reported to cause congenital malformations, stillbirths, and neonatal deaths. Commonly reported fetal abnormalities include hypotension, renal dysplasia, anuria/oliguria, oligohydramnios, intrauterine growth retardation, pulmonary hypoplasia, patent ductus arteriosus, and incomplete ossification of the skull.[19][30] Overall, about half of newborns exposed to ACE inhibitors are adversely affected, leading to birth defects.[31][21]

ACE inhibitors are ADEC pregnancy category D and should be avoided in women who are likely to become pregnant.[18] In the U.S., ACE inhibitors must be labeled with a boxed warning concerning the risk of birth defects when taken during the second and third trimester. Their use in the first trimester is also associated with a risk of major congenital malformations, particularly affecting the cardiovascular and central nervous systems.[32]

Overdose edit

Symptoms and Treatment: There are few reports of ACE inhibitor overdose in the literature. The most likely manifestations are hypotension, which may be severe, hyperkalemia, hyponatremia and renal impairment with metabolic acidosis. Treatment should be mainly symptomatic and supportive, with volume expansion using normal saline to correct hypotension and improve renal function, and gastric lavage followed by activated charcoal and a cathartic to prevent further absorption of the drug. Captopril, enalapril, lisinopril and perindopril are known to be removable by hemodialysis.[33]

Contraindications and precautions edit

The ACE inhibitors are contraindicated in people with:

  • Pregnancy or breastfeeding
  • Previous angioedema associated with ACE inhibitor therapy
  • Bilateral renal artery stenosis[34][35]
  • Hypersensitivity to ACE inhibitors[35]

ACE inhibitors should be used with caution in people with:

A combination of ACE inhibitor with other drugs may increase effects of these drugs, but also the risk of adverse effects.[19] The commonly reported adverse effects of drug combination with ACE inhibitor are acute renal failure, hypotension, and hyperkalemia. The drugs interacting with ACE inhibitor should be prescribed with caution. Special attention should be given to combinations of ACE inhibitor with other RAAS blockers, diuretics (especially potassium-sparing diuretics), NSAIDs, anticoagulants, cyclosporine, DPP-4 inhibitors, and potassium supplements.

Potassium supplementation should be used with caution and under medical supervision owing to the hyperkalemic effect of ACE inhibitors.[36]

Concomitant use with cyclooxygenase inhibitors tends to decrease ACE inhibitor's hypotensive effect.[37][21]

Mechanism of action edit

ACE inhibitors reduce the activity of the renin–angiotensin–aldosterone system (RAAS) as the primary etiologic (causal) event in the development of hypertension in people with diabetes mellitus, as part of the insulin-resistance syndrome or as a manifestation of renal disease.[38][39]

Renin–angiotensin–aldosterone system edit

Main article: Renin–angiotensin system
 
Renin–angiotensin–aldosterone system

The renin–angiotensin–aldosterone system is a major blood pressure regulating mechanism. Markers of electrolyte and water imbalance in the body such as hypotension, low distal tubule sodium concentration, decreased blood volume and high sympathetic tone trigger the release of the enzyme renin from the cells of juxtaglomerular apparatus in the kidney.

Renin activates a circulating liver derived prohormone angiotensinogen by proteolytic cleavage of all but its first ten amino acid residues known as angiotensin I. ACE (angiotensin converting enzyme) then removes a further two residues, converting angiotensin I into angiotensin II. ACE is found in the pulmonary circulation and in the endothelium of many blood vessels.[40] The system increases blood pressure by increasing the amount of salt and water the body retains, although angiotensin is also very good at causing the blood vessels to tighten (a potent vasoconstrictor).

Effects edit

ACE inhibitors block the conversion of angiotensin I (ATI) to angiotensin II (ATII).[41] They thereby lower arteriolar resistance and increase venous capacity; decrease cardiac output, cardiac index, stroke work, and volume; lower resistance in blood vessels in the kidneys; and lead to increased natriuresis (excretion of sodium in the urine). Renin increases in concentration in the blood as a result of negative feedback of conversion of ATI to ATII. ATI increases for the same reason; ATII and aldosterone decrease. Bradykinin increases because of less inactivation by ACE.

Under normal conditions, angiotensin II has these effects:

  • Vasoconstriction (narrowing of blood vessels) and vascular smooth muscle hypertrophy (enlargement) induced by ATII may lead to increased blood pressure and hypertension. Further, constriction of the efferent arterioles of the kidney leads to increased perfusion pressure in the glomeruli.
  • It contributes to ventricular remodeling and ventricular hypertrophy of the heart through stimulation of the proto-oncogenes c-fos, c-jun, c-myc, transforming growth factor beta (TGF-B), through fibrogenesis and apoptosis (programmed cell death).
  • Stimulation by ATII of the adrenal cortex to release aldosterone, a hormone that acts on kidney tubules, causes sodium and chloride ions retention and potassium excretion. Sodium is a "water-holding" ion, so water is also retained, which leads to increased blood volume, hence an increase in blood pressure.
  • Stimulation of the posterior pituitary to release vasopressin (antidiuretic hormone, ADH) also acts on the kidneys to increase water retention. If ADH production is excessive in heart failure, Na+ level in the plasma may fall (hyponatremia), and this is a sign of increased risk of death in heart failure patients.
  • A decrease renal protein kinase C

During the course of ACE inhibitor use, the production of ATII is decreased,[note 1][42] which prevents aldosterone release from the adrenal cortex.[42] This allows the kidney to excrete sodium ions along with obligate water, and retain potassium ions. This decreases blood volume, leading to decreased blood pressure.[42]

Epidemiological and clinical studies have shown ACE inhibitors reduce the progress of diabetic nephropathy independently from their blood pressure-lowering effect.[43] This action of ACE inhibitors is used in the prevention of diabetic renal failure.

ACE inhibitors have been shown to be effective for indications other than hypertension[44] even in patients with normal blood pressure.[45] The use of a maximum dose of ACE inhibitors in such patients (including for prevention of diabetic nephropathy, congestive heart failure, and prophylaxis of cardiovascular events) is justified,[46] because it improves clinical outcomes independently of the blood pressure-lowering effect of ACE inhibitors. Such therapy, of course, requires careful and gradual titration of the dose to prevent the effects of rapidly decreasing blood pressure (dizziness, fainting, etc.).

ACE inhibitors have also been shown to cause a central enhancement of parasympathetic nervous system activity in healthy volunteers and patients with heart failure.[47][48] This action may reduce the prevalence of malignant cardiac arrhythmias, and the reduction in sudden death reported in large clinical trials.[49] ACE Inhibitors also reduce plasma norepinephrine levels, and its resulting vasoconstriction effects, in heart failure patients, thus breaking the vicious circles of sympathetic and renin angiotensin system activation, which sustains the downward spiral in cardiac function in congestive heart failure

The ACE inhibitor enalapril has also been shown to reduce cardiac cachexia in patients with chronic heart failure.[50] Cachexia is a poor prognostic sign in patients with chronic heart failure.[51] ACE inhibitors are under early investigation for the treatment of frailty and muscle wasting (sarcopenia) in elderly patients without heart failure.[52]

Examples edit

Currently, there are 10 ACE inhibitors approved for use in the United States by the FDA: captopril (1981), enalapril (1985), lisinopril (1987), benazepril (1991), fosinopril (1991), quinapril (1991), ramipril (1991), perindopril (1993), moexipril (1995) and trandolapril (1996).[53][54]

ACE inhibitors are easily identifiable by their common suffix, '-pril'. ACE inhibitors can be divided into three groups based on their molecular structure of the enzyme binding sites (sulfhydryl, phosphinyl, carboxyl) to the active center of ACE:[55]

Sulfhydryl-containing agents edit

These agents appear to show antioxidative properties but may be involved in adverse events such as skin eruptions.[55]

Dicarboxylate-containing agents edit

This is the largest group, including:

Phosphonate-containing agents edit

Naturally occurring edit

  • A comprehensive resource on anti-hypertensive peptides is available in form of a database. It contains around 1700 unique antihypertensive peptides[56]
  • Arfalasin (HOE 409) is angiotensin antagonist.[57]

Dairy products edit

Comparative information edit

All ACE inhibitors have similar antihypertensive efficacy when equivalent doses are administered. The main differences lie with captopril, the first ACE inhibitor. Captopril has a shorter duration of action and an increased incidence of adverse effects. It is also the only ACE inhibitor capable of passing through the blood–brain barrier, although the significance of this characteristic has not been shown to have any positive clinical effects.

In a large clinical study, one of the agents in the ACE inhibitor class, ramipril (Altace), demonstrated an ability to reduce the mortality rates of patients with a myocardial infarction and to slow the subsequent development of heart failure. This finding was made after it was discovered that regular use of ramipril reduced mortality rates even in test subjects who didn't have hypertension.[62]

Some believe ramipril's additional benefits may be shared by some or all drugs in the ACE-inhibitor class. However, ramipril currently remains the only ACE inhibitor for which such effects are actually evidence-based.[63]

A meta-analysis confirmed that ACE inhibitors are effective and certainly the first-line choice in hypertension treatment. This meta-analysis was based on 20 trials and a cohort of 158,998 patients, of whom 91% were hypertensive. ACE inhibitors were used as the active treatment in seven trials (n=76,615) and angiotensin receptor blocker (ARB) in 13 trials (n=82,383). ACE inhibitors were associated with a statistically significant 10% mortality reduction: (HR 0.90; 95% CI, 0.84–0.97; P=0.004). In contrast, no significant mortality reduction was observed with ARB treatment (HR 0.99; 95% CI, 0.94–1.04; P=0.683). Analysis of mortality reduction by different ACE inhibitors showed that perindopril-based regimens are associated with a statistically significant 13% all-cause mortality reduction. Taking into account the broad spectrum of the hypertensive population, one might expect that an effective treatment with ACE inhibitors, in particular with perindopril, would result in an important gain of lives saved.[64]

Equivalent doses in hypertension edit

The ACE inhibitors have different strengths with different starting dosages. Dosage should be adjusted according to the clinical response.[65][66][67]

ACE inhibitors dosages for hypertension
Dosage
Note: bid = two times a day, tid = three times a day, d = daily
Drug dosages from Drug Lookup, Epocrates Online.
Name Equivalent daily dose Start Usual Maximum
Benazepril 10 mg 10 mg 20–40 mg 80 mg
Captopril 50 mg (25 mg bid) 12.5–25 mg bid-tid 25–50 mg bid-tid 150 mg/d
Enalapril 5 mg 5 mg 10–40 mg 40 mg
Fosinopril 10 mg 10 mg 20–40 mg 80 mg
Lisinopril 10 mg 10 mg 10–40 mg 80 mg
Moexipril 7.5 mg 7.5 mg 7.5–30 mg 30 mg
Perindopril 4 mg 4 mg 4–8 mg 16 mg
Quinapril 10 mg 10 mg 20–80 mg 80 mg
Ramipril 2.5 mg 2.5 mg 2.5–20 mg 20 mg
Trandolapril 2 mg 1 mg 2–4 mg 8 mg

Combination with angiotensin II receptor antagonists edit

ACE inhibitors possess many common characteristics with another class of cardiovascular drugs, angiotensin II receptor antagonists, which are often used when patients are intolerant of the adverse effects produced by ACE inhibitors. ACE inhibitors do not completely prevent the formation of angiotensin II, as blockage is dose-dependent, so angiotensin II receptor antagonists may be useful because they act to prevent the action of angiotensin II at the AT1 receptor, leaving AT2 receptor unblocked; the latter may have consequences needing further study.

The combination therapy of angiotensin II receptor antagonists with ACE inhibitors may be superior to either agent alone. This combination may increase levels of bradykinin while blocking the generation of angiotensin II and its activity at the AT1 receptor. This 'dual blockade' may be more effective than using an ACE inhibitor alone, because angiotensin II can be generated via non-ACE-dependent pathways. Preliminary studies suggest this combination of pharmacologic agents may be advantageous in the treatment of essential hypertension, chronic heart failure,[68] and nephropathy.[69][70] However, the more recent ONTARGET study showed no benefit of combining the agents and more adverse events.[71] While statistically significant results have been obtained for its role in treating hypertension, clinical significance may be lacking.[72] There are warnings about the combination of ACE inhibitors with ARBs.[73]

Patients with heart failure may benefit from the combination in terms of reducing morbidity and ventricular remodeling.[74][75]

The most compelling evidence for the treatment of nephropathy has been found: This combination therapy partially reversed the proteinuria and also exhibited a renoprotective effect in patients with diabetic nephropathy,[69] and pediatric IgA nephropathy.[76]

History edit

Main article: ACE inhibitors drug design

Leonard T. Skeggs and his colleagues (including Norman Shumway) discovered ACE in plasma in 1956.[77] It was also noted that those who worked in banana plantations in South-western Brazil collapsed after being bitten by a pit viper, leading to a search for a blood pressure lowering component in its venom.[78] Brazilian scientist Sérgio Henrique Ferreira reported a bradykinin-potentiating factor (BPF) present in the venom of Bothrops jararaca, a South American pit viper, in 1965.[79] Ferreira then went to John Vane's laboratory as a postdoctoral fellow with his already-isolated BPF. The conversion of the inactive angiotensin I to the potent angiotensin II was thought to take place in the plasma. However, in 1967, Kevin K. F. Ng and John R. Vane showed plasma ACE is too slow to account for the conversion of angiotensin I to angiotensin II in vivo. Subsequent investigation showed rapid conversion occurs during its passage through the pulmonary circulation.[80]

Bradykinin is rapidly inactivated in the circulating blood, and it disappears completely in a single pass through the pulmonary circulation. Angiotensin I also disappears in the pulmonary circulation because of its conversion to angiotensin II. Furthermore, angiotensin II passes through the lungs without any loss. The inactivation of bradykinin and the conversion of angiotensin I to angiotensin II in the lungs was thought to be caused by the same enzyme.[81] In 1970, Ng and Vane, using BPF provided by Ferreira, showed the conversion is inhibited during its passage through the pulmonary circulation.[82]

BPFs are members of a family of peptides whose potentiating action is linked to inhibition of bradykinin by ACE. Molecular analysis of BPF yielded a nonapeptide BPF teprotide (SQ 20,881), which showed the greatest ACE inhibition potency and hypotensive effect in vivo. Teprotide had limited clinical value as a result of its peptide nature and lack of activity when given orally. In the early 1970s, knowledge of the structure-activity relationship required for inhibition of ACE was growing. David Cushman, Miguel Ondetti and colleagues used peptide analogues to study the structure of ACE, using carboxypeptidase A as a model. Their discoveries led to the development of captopril, the first orally-active ACE inhibitor, in 1975.[83]

Captopril was approved by the United States Food and Drug Administration in 1981.[84] The first nonsulfhydryl-containing ACE inhibitor, enalapril, was approved four years later.[85] At least 8 other ACE inhibitors have since been marketed.[86]

In 1991, Japanese scientists created the first milk-based ACE inhibitor, in the form of a fermented milk drink, using specific cultures to liberate the tripeptide isoleucine-proline-proline (IPP) from the dairy protein. Valine-proline-proline (VPP) is also liberated in this process—another milk tripeptide with a very similar chemical structure to IPP. Together, these peptides are now often referred to as lactotripeptides. In 1996, the first human study confirmed the blood pressure-lowering effect of IPP in fermented milk.[87] Although twice the amount of VPP is needed to achieve the same ACE-inhibiting activity as the originally discovered IPP, VPP also is assumed to add to the total blood pressure lowering effect.[88] Since the first lactotripeptides discovery, more than 20 human clinical trials have been conducted in many different countries.[60]

Note edit

  1. ^ ACE inhibitors don't appear to permanently reduce ATII plasma level after cessation of taking it. In short, ACE inhibitors don't cure high ATII plasma levels.[42]

See also edit

References edit

  1. ^ a b c d Kaplan's Essentials of Cardiac Anesthesia. Elsevier. 2018. doi:10.1016/c2012-0-06151-0. ISBN 978-0-323-49798-5. Mechanisms of Action:ACE inhibitors act by inhibiting one of several proteases responsible for cleaving the decapeptide Ang I to form the octapeptide Ang II. Because ACE is also the enzyme that degrades bradykinin, ACE inhibitors increase circulating and tissue levels of bradykinin (Fig. 8.4).
  2. ^ Aronow, Wilbert S. (2010). "Cardiac Arrhythmias". Brocklehurst's Textbook of Geriatric Medicine and Gerontology. Elsevier. pp. 327–337. doi:10.1016/b978-1-4160-6231-8.10045-5. ISBN 978-1-4160-6231-8. Angiotensin-converting enzyme inhibitors ACE inhibitors have been demonstrated to reduce sudden cardiac death in some studies of persons with CHF.24,56
  3. ^ a b c Byrd, James Brian; Ram, C. Venkata S.; Lerma, Edgar V. (2019). "Pharmacologic treatment of hypertension". Nephrology Secrets. Elsevier. pp. 477–482. doi:10.1016/b978-0-323-47871-7.00078-2. ISBN 978-0-323-47871-7. ACE inhibitors inhibit the conversion of angiotensin I to angiotensin II, thereby producing vasodilation and lowering BP. Because the hydrolysis of bradykinin is also inhibited by these drugs, cough (7% to 12%) can occur.
  4. ^ Jackson, Edwin K. (2006). "Chapter 30. Renin and Angiotensin". In Brunton, Laurence L.; Lazo, John S.; Parker, Keith (eds.). Goodman & Gilman's The Pharmacological Basis of Therapeutics (11th ed.). New York: McGraw-Hill. ISBN 978-0-07-142280-2.
  5. ^ "Myocardial Infarction". The Lecturio Medical Concept Library. Retrieved 27 August 2021.
  6. ^ "Congestive Heart Failure". The Lecturio Medical Concept Library. 7 August 2020. Retrieved 27 August 2021.
  7. ^ Kester, Mark; Karpa, Kelly D.; Vrana, Kent E. (2012). "Cardiovascular System". Elsevier's Integrated Review Pharmacology. Elsevier. pp. 125–151. doi:10.1016/b978-0-323-07445-2.00008-2. ISBN 978-0-323-07445-2. ACE inhibitors also slow progression of kidney disease in patients with diabetic nephropathies. Renal benefits are probably a result of improved renal hemodynamics from decreased glomerular arteriolar resistance.
  8. ^ "Type 2 diabetes in adults: management". www.nice.org.uk. National Institute for Health and Care Excellence (NICE). May 2017. Retrieved October 25, 2018.
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  11. ^ Caldeira, Daniel (Summer 2012). "Risk of pneumonia associated with use of angiotensin converting enzyme inhibitors and angiotensin receptor blockers: systematic review and meta-analysis". BMJ. 345: 4260. doi:10.1136/bmj.e4260. PMC 3394697. PMID 22786934.
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  16. ^ Vlahakos, Demetrios V.; Marathias, Katerina P.; Agroyannis, Basil; Madias, Nicolaos E. (2003-04-01). "Posttransplant erythrocytosis". Kidney International. 63 (4): 1187–1194. doi:10.1046/j.1523-1755.2003.00850.x. ISSN 0085-2538. PMID 12631334.
  17. ^ Cruzado, Josep M.; Rico, Jorge; Grinyó, Josep M. (April 2008). "The renin angiotensin system blockade in kidney transplantation: pros and cons". Transplant International. 21 (4): 304–313. doi:10.1111/j.1432-2277.2008.00638.x. PMID 18266774. S2CID 24893488.
  18. ^ a b Rossi S, editor. Australian Medicines Handbook 2006. Adelaide: Australian Medicines Handbook; 2006. ISBN 0-9757919-2-3.[page needed]
  19. ^ a b c d e f g Sidorenkov G, Navis G (2014). "Safety of ACE inhibitor therapies in patients with chronic kidney disease". Expert Opinion on Drug Safety. 13 (10): 1383–1395. doi:10.1517/14740338.2014.951328. PMID 25148900. S2CID 207488068.
  20. ^ a b Tucker, Bryan M.; Perazella, Mark A. (2019). "Medications: 3. What are the major adverse effects on the kidney of ACE inhibitors and ARBs?". Nephrology Secrets. Elsevier. pp. 78–83. doi:10.1016/b978-0-323-47871-7.00019-8. ISBN 978-0-323-47871-7. due to inhibition of angiotensin II production by ACE inhibitors or competitive antagonism of the angiotensin II receptor by ARBs... results in loss of angiotensin II–induced efferent arteriolar tone, leading to a drop in glomerular filtration fraction and GFR. The efferent arteriolal vasodilation reduces intraglomerular hypertension (and pressure-related injury) and maintains perfusion (and oxygenation) of the peritubular capillaries.
  21. ^ a b c d Byrd, James Brian; Ram, C. Venkata S.; Lerma, Edgar V. (2019). "Pharmacologic treatment of hypertension". Nephrology Secrets. Elsevier. pp. 477–482. doi:10.1016/b978-0-323-47871-7.00078-2. ISBN 978-0-323-47871-7. Angioedema (0.7%) can also occur via pathobiology that remains obscure, and its occurrence can be life-threatening. ...their efficacy is reduced by dietary or other sources of sodium, and renal function may be further threatened if given with NSAIDs.
  22. ^ Thomas MC (2000). "Diuretics, ACE inhibitors and NSAIDs—the triple whammy". The Medical Journal of Australia. 172 (4): 184–5. doi:10.5694/j.1326-5377.2000.tb125548.x. PMID 10772593. S2CID 37558579.
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  • From snake venom to ACE inhibitor — the discovery and rise of captopril

December 18, 2023
inhibitor, acei, redirects, here, other, uses, acei, disambiguation, confused, with, acetylcholinesterase, inhibitor, angiotensin, converting, enzyme, inhibitors, class, medication, used, primarily, treatment, high, blood, pressure, heart, failure, this, class. ACEI redirects here For other uses see acei disambiguation Not to be confused with Acetylcholinesterase inhibitor Angiotensin converting enzyme inhibitors ACE inhibitors are a class of medication used primarily for the treatment of high blood pressure and heart failure 1 2 This class of medicine works by causing relaxation of blood vessels as well as a decrease in blood volume which leads to lower blood pressure and decreased oxygen demand from the heart Angiotensin converting enzyme inhibitorDrug classCaptopril the first synthetic ACE inhibitorClass identifiersUseHypertensionATC codeC09ABiological targetAngiotensin converting enzymeClinical dataDrugs comDrug ClassesConsumer ReportsBest Buy DrugsWebMDMedicineNet RxListExternal linksMeSHD000806Legal statusIn WikidataACE inhibitors inhibit the activity of angiotensin converting enzyme an important component of the renin angiotensin system which converts angiotensin I to angiotensin II 3 and hydrolyses bradykinin 1 Therefore ACE inhibitors decrease the formation of angiotensin II a vasoconstrictor and increase the level of bradykinin a peptide vasodilator 1 3 This combination is synergistic in lowering blood pressure 1 3 As a result of inhibiting the ACE enzyme in the bradykinin system the ACE inhibitor drugs allow for increased levels of bradykinin which would normally be degraded Bradykinin produces prostaglandin This mechanism can explain the two most common side effects seen with ACE Inhibitors angioedema and cough Frequently prescribed ACE inhibitors include benazepril zofenopril perindopril trandolapril captopril enalapril lisinopril and ramipril Contents 1 Medical use 1 1 Other 2 Adverse effects 2 1 Blood 2 2 Pregnancy 3 Overdose 4 Contraindications and precautions 5 Mechanism of action 5 1 Renin angiotensin aldosterone system 5 2 Effects 6 Examples 6 1 Sulfhydryl containing agents 6 2 Dicarboxylate containing agents 6 3 Phosphonate containing agents 6 4 Naturally occurring 6 4 1 Dairy products 7 Comparative information 7 1 Equivalent doses in hypertension 8 Combination with angiotensin II receptor antagonists 9 History 10 Note 11 See also 12 References 13 External linksMedical use editACE inhibitors were initially approved for the treatment of hypertension and can be used alone or in combination with other anti hypertensive medications Later they were found useful for other cardiovascular and kidney diseases 4 including Acute myocardial infarction heart attack 5 Heart failure left ventricular systolic dysfunction 6 Kidney complications of diabetes mellitus diabetic nephropathy by means of decreasing the blood pressure and increasing perfusion in glomerular arterioles 7 In treating high blood pressure ACE inhibitors are often the first drug choice particularly when diabetes is present 8 but age can lead to different choices and it is common to need more than one drug to obtain the desired improvement There are fixed dose combination drugs such as ACE inhibitor and thiazide combinations ACE inhibitors have also been used in chronic kidney failure and kidney involvement in systemic sclerosis hardening of tissues as scleroderma renal crisis In those with stable coronary artery disease but no heart failure benefits are similar to other usual treatments 9 In 2012 there was a meta analysis published in the BMJ that described the protective role of ACE inhibitors in reducing the risk of pneumonia when compared to angiotensin II receptor blocker ARBs 10 The authors found a decreased risk in patients with previous stroke 54 risk reduction with heart failure 37 risk reduction and of Asian descent 43 risk reduction vs 54 risk reduction in non Asian population However no reduced pneumonia related mortality was observed 11 Other edit ACE inhibitors may also be used to help decrease excessive water consumption in people with schizophrenia resulting in psychogenic polydipsia 12 13 A double blind placebo controlled trial showed that when used for this purpose enalapril led to decreased consumption determined by urine output and osmolality in 60 of people 14 the same effect has been demonstrated in other ACE inhibitors 15 Additionally ACE I are commonly used after renal transplant to manage post transplant erythrocytosis a condition characterised by a persistently high hematocrit greater than 51 which often develops 8 24 months after successful transplantation 16 as ACE I have been shown to decrease erythropoietin production 17 Adverse effects editCommon side effects include low blood pressure cough hyperkalemia headache dizziness fatigue nausea and kidney impairment 18 19 The main adverse effects of ACE inhibition can be understood from their pharmacological action The other reported adverse effects are liver problems and effects on the fetus 19 Kidney problems may occur with all ACE inhibitors that directly follows from their mechanism of action Patients starting on an ACE inhibitor usually have a modest reduction in glomerular filtration rate GFR 20 However the decrease may be significant in conditions of pre existing decreased renal perfusions such as renal artery stenosis heart failure polycystic kidney disease or volume depletion In these patients the maintenance of GFR depends on angiotensin II dependent efferent vasomotor tone 20 Therefore renal function should be closely monitored over the first few days after initiation of treatment with ACE inhibitor in patients with decreased renal perfusion 19 A moderate reduction in renal function no greater than 30 rise in serum creatinine that is stabilized after a week of treatment is deemed acceptable as part of the therapeutic effect providing the residual renal function is sufficient Reduced GFR is especially a problem if the patient is concomitantly taking an NSAID and a diuretic 21 When the three drugs are taken together the risk of developing renal failure is significantly increased 22 High blood potassium is another possible complication of treatment with an ACE inhibitor due to its effect on aldosterone Suppression of angiotensin II leads to a decrease in aldosterone levels Since aldosterone is responsible for increasing the excretion of potassium ACE inhibitors can cause retention of potassium Some people however can continue to lose potassium while on an ACE inhibitor 23 Hyperkalemia may decrease the velocity of impulse conduction in the nerves and muscles including cardiac tissues This leads to cardiac dysfunction and neuromuscular consequences such as muscle weakness paresthesia nausea diarrhea and others Close monitoring of potassium levels is required in patients receiving treatment with ACE inhibitors who are at risk of hyperkalemia 19 Another possible adverse effect specific for ACE inhibitors but not for other RAAS blockers is an increase in bradykinin level 19 A persistent dry cough is a relatively common adverse effect believed to be associated with the increases in bradykinin levels produced by ACE inhibitors although the role of bradykinin in producing these symptoms has been disputed 24 Many cases of cough in people on ACE inhibitors may not be from the medication itself however 25 People who experience this cough are often switched to angiotensin II receptor antagonists Some 0 7 21 develop angioedema due to increased bradykinin levels 26 A genetic predisposition may exist 27 A severe rare allergic reaction can affect the bowel wall and secondarily cause abdominal pain 28 Blood edit Hematologic effects such as neutropenia agranulocytosis and other blood dyscrasias have occurred during therapy with ACE inhibitors especially in people with additional risk factors 29 Pregnancy edit In pregnant women ACE inhibitors taken during all the trimesters have been reported to cause congenital malformations stillbirths and neonatal deaths Commonly reported fetal abnormalities include hypotension renal dysplasia anuria oliguria oligohydramnios intrauterine growth retardation pulmonary hypoplasia patent ductus arteriosus and incomplete ossification of the skull 19 30 Overall about half of newborns exposed to ACE inhibitors are adversely affected leading to birth defects 31 21 ACE inhibitors are ADEC pregnancy category D and should be avoided in women who are likely to become pregnant 18 In the U S ACE inhibitors must be labeled with a boxed warning concerning the risk of birth defects when taken during the second and third trimester Their use in the first trimester is also associated with a risk of major congenital malformations particularly affecting the cardiovascular and central nervous systems 32 Overdose editSymptoms and Treatment There are few reports of ACE inhibitor overdose in the literature The most likely manifestations are hypotension which may be severe hyperkalemia hyponatremia and renal impairment with metabolic acidosis Treatment should be mainly symptomatic and supportive with volume expansion using normal saline to correct hypotension and improve renal function and gastric lavage followed by activated charcoal and a cathartic to prevent further absorption of the drug Captopril enalapril lisinopril and perindopril are known to be removable by hemodialysis 33 Contraindications and precautions editThe ACE inhibitors are contraindicated in people with Pregnancy or breastfeeding Previous angioedema associated with ACE inhibitor therapy Bilateral renal artery stenosis 34 35 Hypersensitivity to ACE inhibitors 35 ACE inhibitors should be used with caution in people with Impaired renal function Aortic valve stenosis or cardiac outflow obstruction Hypovolemia or dehydration Hemodialysis with high flux polyacrylonitrile membranesA combination of ACE inhibitor with other drugs may increase effects of these drugs but also the risk of adverse effects 19 The commonly reported adverse effects of drug combination with ACE inhibitor are acute renal failure hypotension and hyperkalemia The drugs interacting with ACE inhibitor should be prescribed with caution Special attention should be given to combinations of ACE inhibitor with other RAAS blockers diuretics especially potassium sparing diuretics NSAIDs anticoagulants cyclosporine DPP 4 inhibitors and potassium supplements Potassium supplementation should be used with caution and under medical supervision owing to the hyperkalemic effect of ACE inhibitors 36 Concomitant use with cyclooxygenase inhibitors tends to decrease ACE inhibitor s hypotensive effect 37 21 Mechanism of action editACE inhibitors reduce the activity of the renin angiotensin aldosterone system RAAS as the primary etiologic causal event in the development of hypertension in people with diabetes mellitus as part of the insulin resistance syndrome or as a manifestation of renal disease 38 39 Renin angiotensin aldosterone system edit Main article Renin angiotensin system nbsp Renin angiotensin aldosterone systemThe renin angiotensin aldosterone system is a major blood pressure regulating mechanism Markers of electrolyte and water imbalance in the body such as hypotension low distal tubule sodium concentration decreased blood volume and high sympathetic tone trigger the release of the enzyme renin from the cells of juxtaglomerular apparatus in the kidney Renin activates a circulating liver derived prohormone angiotensinogen by proteolytic cleavage of all but its first ten amino acid residues known as angiotensin I ACE angiotensin converting enzyme then removes a further two residues converting angiotensin I into angiotensin II ACE is found in the pulmonary circulation and in the endothelium of many blood vessels 40 The system increases blood pressure by increasing the amount of salt and water the body retains although angiotensin is also very good at causing the blood vessels to tighten a potent vasoconstrictor Effects edit ACE inhibitors block the conversion of angiotensin I ATI to angiotensin II ATII 41 They thereby lower arteriolar resistance and increase venous capacity decrease cardiac output cardiac index stroke work and volume lower resistance in blood vessels in the kidneys and lead to increased natriuresis excretion of sodium in the urine Renin increases in concentration in the blood as a result of negative feedback of conversion of ATI to ATII ATI increases for the same reason ATII and aldosterone decrease Bradykinin increases because of less inactivation by ACE Under normal conditions angiotensin II has these effects Vasoconstriction narrowing of blood vessels and vascular smooth muscle hypertrophy enlargement induced by ATII may lead to increased blood pressure and hypertension Further constriction of the efferent arterioles of the kidney leads to increased perfusion pressure in the glomeruli It contributes to ventricular remodeling and ventricular hypertrophy of the heart through stimulation of the proto oncogenes c fos c jun c myc transforming growth factor beta TGF B through fibrogenesis and apoptosis programmed cell death Stimulation by ATII of the adrenal cortex to release aldosterone a hormone that acts on kidney tubules causes sodium and chloride ions retention and potassium excretion Sodium is a water holding ion so water is also retained which leads to increased blood volume hence an increase in blood pressure Stimulation of the posterior pituitary to release vasopressin antidiuretic hormone ADH also acts on the kidneys to increase water retention If ADH production is excessive in heart failure Na level in the plasma may fall hyponatremia and this is a sign of increased risk of death in heart failure patients A decrease renal protein kinase CDuring the course of ACE inhibitor use the production of ATII is decreased note 1 42 which prevents aldosterone release from the adrenal cortex 42 This allows the kidney to excrete sodium ions along with obligate water and retain potassium ions This decreases blood volume leading to decreased blood pressure 42 Epidemiological and clinical studies have shown ACE inhibitors reduce the progress of diabetic nephropathy independently from their blood pressure lowering effect 43 This action of ACE inhibitors is used in the prevention of diabetic renal failure ACE inhibitors have been shown to be effective for indications other than hypertension 44 even in patients with normal blood pressure 45 The use of a maximum dose of ACE inhibitors in such patients including for prevention of diabetic nephropathy congestive heart failure and prophylaxis of cardiovascular events is justified 46 because it improves clinical outcomes independently of the blood pressure lowering effect of ACE inhibitors Such therapy of course requires careful and gradual titration of the dose to prevent the effects of rapidly decreasing blood pressure dizziness fainting etc ACE inhibitors have also been shown to cause a central enhancement of parasympathetic nervous system activity in healthy volunteers and patients with heart failure 47 48 This action may reduce the prevalence of malignant cardiac arrhythmias and the reduction in sudden death reported in large clinical trials 49 ACE Inhibitors also reduce plasma norepinephrine levels and its resulting vasoconstriction effects in heart failure patients thus breaking the vicious circles of sympathetic and renin angiotensin system activation which sustains the downward spiral in cardiac function in congestive heart failureThe ACE inhibitor enalapril has also been shown to reduce cardiac cachexia in patients with chronic heart failure 50 Cachexia is a poor prognostic sign in patients with chronic heart failure 51 ACE inhibitors are under early investigation for the treatment of frailty and muscle wasting sarcopenia in elderly patients without heart failure 52 Examples editCurrently there are 10 ACE inhibitors approved for use in the United States by the FDA captopril 1981 enalapril 1985 lisinopril 1987 benazepril 1991 fosinopril 1991 quinapril 1991 ramipril 1991 perindopril 1993 moexipril 1995 and trandolapril 1996 53 54 ACE inhibitors are easily identifiable by their common suffix pril ACE inhibitors can be divided into three groups based on their molecular structure of the enzyme binding sites sulfhydryl phosphinyl carboxyl to the active center of ACE 55 Sulfhydryl containing agents edit Alacepril 55 Captopril trade name Capoten the first ACE inhibitor 55 ZofenoprilThese agents appear to show antioxidative properties but may be involved in adverse events such as skin eruptions 55 Dicarboxylate containing agents edit This is the largest group including Enalapril Vasotec Renitec Berlipril Enap Enalapril Profarma Ramipril Altace Prilace Ramace Ramiwin Triatec Tritace Ramitac Quinapril Accupril Perindopril Coversyl Aceon Perindo Lisinopril Listril Lopril Novatec Prinivil Zestril Lisidigal Benazepril Lotensin Imidapril Tanatril Trandolapril Mavik Odrik Gopten Cilazapril Inhibace Phosphonate containing agents edit Ceronapril never marketed Fosinopril Fositen Monopril Naturally occurring edit A comprehensive resource on anti hypertensive peptides is available in form of a database It contains around 1700 unique antihypertensive peptides 56 Arfalasin HOE 409 is angiotensin antagonist 57 Dairy products edit Casokinins and lactokinins breakdown products of casein and whey occur naturally after ingestion of milk products especially cultured milk Their role in blood pressure control is uncertain 58 The lactotripeptides Val Pro Pro and Ile Pro Pro produced by the probiotic Lactobacillus helveticus or derived from casein have been shown to have ACE inhibiting and antihypertensive functions 59 60 In one study L helveticus PR4 was isolated from Italian cheeses 61 Comparative information editAll ACE inhibitors have similar antihypertensive efficacy when equivalent doses are administered The main differences lie with captopril the first ACE inhibitor Captopril has a shorter duration of action and an increased incidence of adverse effects It is also the only ACE inhibitor capable of passing through the blood brain barrier although the significance of this characteristic has not been shown to have any positive clinical effects In a large clinical study one of the agents in the ACE inhibitor class ramipril Altace demonstrated an ability to reduce the mortality rates of patients with a myocardial infarction and to slow the subsequent development of heart failure This finding was made after it was discovered that regular use of ramipril reduced mortality rates even in test subjects who didn t have hypertension 62 Some believe ramipril s additional benefits may be shared by some or all drugs in the ACE inhibitor class However ramipril currently remains the only ACE inhibitor for which such effects are actually evidence based 63 A meta analysis confirmed that ACE inhibitors are effective and certainly the first line choice in hypertension treatment This meta analysis was based on 20 trials and a cohort of 158 998 patients of whom 91 were hypertensive ACE inhibitors were used as the active treatment in seven trials n 76 615 and angiotensin receptor blocker ARB in 13 trials n 82 383 ACE inhibitors were associated with a statistically significant 10 mortality reduction HR 0 90 95 CI 0 84 0 97 P 0 004 In contrast no significant mortality reduction was observed with ARB treatment HR 0 99 95 CI 0 94 1 04 P 0 683 Analysis of mortality reduction by different ACE inhibitors showed that perindopril based regimens are associated with a statistically significant 13 all cause mortality reduction Taking into account the broad spectrum of the hypertensive population one might expect that an effective treatment with ACE inhibitors in particular with perindopril would result in an important gain of lives saved 64 Equivalent doses in hypertension edit The ACE inhibitors have different strengths with different starting dosages Dosage should be adjusted according to the clinical response 65 66 67 ACE inhibitors dosages for hypertensionDosageNote bid two times a day tid three times a day d daily Drug dosages from Drug Lookup Epocrates Online Name Equivalent daily dose Start Usual MaximumBenazepril 10 mg 10 mg 20 40 mg 80 mgCaptopril 50 mg 25 mg bid 12 5 25 mg bid tid 25 50 mg bid tid 150 mg dEnalapril 5 mg 5 mg 10 40 mg 40 mgFosinopril 10 mg 10 mg 20 40 mg 80 mgLisinopril 10 mg 10 mg 10 40 mg 80 mgMoexipril 7 5 mg 7 5 mg 7 5 30 mg 30 mgPerindopril 4 mg 4 mg 4 8 mg 16 mgQuinapril 10 mg 10 mg 20 80 mg 80 mgRamipril 2 5 mg 2 5 mg 2 5 20 mg 20 mgTrandolapril 2 mg 1 mg 2 4 mg 8 mgCombination with angiotensin II receptor antagonists editACE inhibitors possess many common characteristics with another class of cardiovascular drugs angiotensin II receptor antagonists which are often used when patients are intolerant of the adverse effects produced by ACE inhibitors ACE inhibitors do not completely prevent the formation of angiotensin II as blockage is dose dependent so angiotensin II receptor antagonists may be useful because they act to prevent the action of angiotensin II at the AT1 receptor leaving AT2 receptor unblocked the latter may have consequences needing further study The combination therapy of angiotensin II receptor antagonists with ACE inhibitors may be superior to either agent alone This combination may increase levels of bradykinin while blocking the generation of angiotensin II and its activity at the AT1 receptor This dual blockade may be more effective than using an ACE inhibitor alone because angiotensin II can be generated via non ACE dependent pathways Preliminary studies suggest this combination of pharmacologic agents may be advantageous in the treatment of essential hypertension chronic heart failure 68 and nephropathy 69 70 However the more recent ONTARGET study showed no benefit of combining the agents and more adverse events 71 While statistically significant results have been obtained for its role in treating hypertension clinical significance may be lacking 72 There are warnings about the combination of ACE inhibitors with ARBs 73 Patients with heart failure may benefit from the combination in terms of reducing morbidity and ventricular remodeling 74 75 The most compelling evidence for the treatment of nephropathy has been found This combination therapy partially reversed the proteinuria and also exhibited a renoprotective effect in patients with diabetic nephropathy 69 and pediatric IgA nephropathy 76 History editMain article ACE inhibitors drug design Leonard T Skeggs and his colleagues including Norman Shumway discovered ACE in plasma in 1956 77 It was also noted that those who worked in banana plantations in South western Brazil collapsed after being bitten by a pit viper leading to a search for a blood pressure lowering component in its venom 78 Brazilian scientist Sergio Henrique Ferreira reported a bradykinin potentiating factor BPF present in the venom of Bothrops jararaca a South American pit viper in 1965 79 Ferreira then went to John Vane s laboratory as a postdoctoral fellow with his already isolated BPF The conversion of the inactive angiotensin I to the potent angiotensin II was thought to take place in the plasma However in 1967 Kevin K F Ng and John R Vane showed plasma ACE is too slow to account for the conversion of angiotensin I to angiotensin II in vivo Subsequent investigation showed rapid conversion occurs during its passage through the pulmonary circulation 80 Bradykinin is rapidly inactivated in the circulating blood and it disappears completely in a single pass through the pulmonary circulation Angiotensin I also disappears in the pulmonary circulation because of its conversion to angiotensin II Furthermore angiotensin II passes through the lungs without any loss The inactivation of bradykinin and the conversion of angiotensin I to angiotensin II in the lungs was thought to be caused by the same enzyme 81 In 1970 Ng and Vane using BPF provided by Ferreira showed the conversion is inhibited during its passage through the pulmonary circulation 82 BPFs are members of a family of peptides whose potentiating action is linked to inhibition of bradykinin by ACE Molecular analysis of BPF yielded a nonapeptide BPF teprotide SQ 20 881 which showed the greatest ACE inhibition potency and hypotensive effect in vivo Teprotide had limited clinical value as a result of its peptide nature and lack of activity when given orally In the early 1970s knowledge of the structure activity relationship required for inhibition of ACE was growing David Cushman Miguel Ondetti and colleagues used peptide analogues to study the structure of ACE using carboxypeptidase A as a model Their discoveries led to the development of captopril the first orally active ACE inhibitor in 1975 83 Captopril was approved by the United States Food and Drug Administration in 1981 84 The first nonsulfhydryl containing ACE inhibitor enalapril was approved four years later 85 At least 8 other ACE inhibitors have since been marketed 86 In 1991 Japanese scientists created the first milk based ACE inhibitor in the form of a fermented milk drink using specific cultures to liberate the tripeptide isoleucine proline proline IPP from the dairy protein Valine proline proline VPP is also liberated in this process another milk tripeptide with a very similar chemical structure to IPP Together these peptides are now often referred to as lactotripeptides In 1996 the first human study confirmed the blood pressure lowering effect of IPP in fermented milk 87 Although twice the amount of VPP is needed to achieve the same ACE inhibiting activity as the originally discovered IPP VPP also is assumed to add to the total blood pressure lowering effect 88 Since the first lactotripeptides discovery more than 20 human clinical trials have been conducted in many different countries 60 Note edit ACE inhibitors don t appear to permanently reduce ATII plasma level after cessation of taking it In short ACE inhibitors don t cure high ATII plasma levels 42 See also editAngiotensin II receptor blocker Discovery and development of angiotensin receptor blockers Loop diuretic also used to treat CHF Renin inhibitorReferences edit a b c d Kaplan s Essentials of Cardiac Anesthesia Elsevier 2018 doi 10 1016 c2012 0 06151 0 ISBN 978 0 323 49798 5 Mechanisms of Action ACE inhibitors act by inhibiting one of several proteases responsible for cleaving the decapeptide Ang I to form the octapeptide Ang II Because ACE is also the enzyme that degrades bradykinin ACE inhibitors increase circulating and tissue levels of bradykinin Fig 8 4 Aronow Wilbert S 2010 Cardiac Arrhythmias Brocklehurst s Textbook of Geriatric Medicine and Gerontology Elsevier pp 327 337 doi 10 1016 b978 1 4160 6231 8 10045 5 ISBN 978 1 4160 6231 8 Angiotensin converting enzyme inhibitors ACE inhibitors have been demonstrated to reduce sudden cardiac death in some studies of persons with CHF 24 56 a b c Byrd James Brian Ram C Venkata S Lerma Edgar V 2019 Pharmacologic treatment of hypertension Nephrology Secrets Elsevier pp 477 482 doi 10 1016 b978 0 323 47871 7 00078 2 ISBN 978 0 323 47871 7 ACE inhibitors inhibit the conversion of angiotensin I to angiotensin II thereby producing vasodilation and lowering BP Because the hydrolysis of bradykinin is also inhibited by these drugs cough 7 to 12 can occur Jackson Edwin K 2006 Chapter 30 Renin and Angiotensin In Brunton Laurence L Lazo John S Parker Keith eds Goodman amp Gilman s The Pharmacological Basis of Therapeutics 11th ed New York McGraw Hill ISBN 978 0 07 142280 2 Myocardial Infarction The Lecturio Medical Concept Library Retrieved 27 August 2021 Congestive Heart Failure The Lecturio Medical Concept Library 7 August 2020 Retrieved 27 August 2021 Kester Mark Karpa Kelly D Vrana Kent E 2012 Cardiovascular System Elsevier s Integrated Review Pharmacology Elsevier pp 125 151 doi 10 1016 b978 0 323 07445 2 00008 2 ISBN 978 0 323 07445 2 ACE inhibitors also slow progression of kidney disease in patients with diabetic nephropathies Renal benefits are probably a result of improved renal hemodynamics from decreased glomerular arteriolar resistance Type 2 diabetes in adults management www nice org uk National Institute for Health and Care Excellence NICE May 2017 Retrieved October 25 2018 Bangalore S Fakheri R Wandel S Toklu B Wandel J Messerli FH 19 January 2017 Renin angiotensin system inhibitors for patients with stable coronary artery disease without heart failure systematic review and meta analysis of randomized trials BMJ Clinical Research Ed 356 j4 doi 10 1136 bmj j4 PMC 5244819 PMID 28104622 Caldeira D Alarcao J Vaz Carneiro A Costa J 2012 07 11 Risk of pneumonia associated with use of angiotensin converting enzyme inhibitors and angiotensin receptor blockers systematic review and meta analysis The BMJ BMJ 345 jul11 1 e4260 doi 10 1136 bmj e4260 ISSN 1756 1833 PMC 3394697 PMID 22786934 Caldeira Daniel Summer 2012 Risk of pneumonia associated with use of angiotensin converting enzyme inhibitors and angiotensin receptor blockers systematic review and meta analysis BMJ 345 4260 doi 10 1136 bmj e4260 PMC 3394697 PMID 22786934 Psychogenic polydipsia Management Emerging treatments British Medical Journal May 5 2016 Retrieved October 28 2016 Dundas Brian Harris Melissa Narasimhan Meera 2007 07 03 Psychogenic polydipsia review Etiology differential and treatment Current Psychiatry Reports 9 3 236 241 doi 10 1007 s11920 007 0025 7 ISSN 1523 3812 PMID 17521521 S2CID 27207760 Greendyke R M Bernhardt A J Tasbas H E Lewandowski K S 1998 04 01 Polydipsia in chronic psychiatric patients therapeutic trials of clonidine and enalapril Neuropsychopharmacology 18 4 272 281 doi 10 1016 S0893 133X 97 00159 0 ISSN 0893 133X PMID 9509495 Sebastian C S Bernardin A S 1990 04 01 Comparison of enalapril and captopril in the management of self induced water intoxication Biological Psychiatry 27 7 787 790 doi 10 1016 0006 3223 90 90594 r ISSN 0006 3223 PMID 2183881 S2CID 39998447 Vlahakos Demetrios V Marathias Katerina P Agroyannis Basil Madias Nicolaos E 2003 04 01 Posttransplant erythrocytosis Kidney International 63 4 1187 1194 doi 10 1046 j 1523 1755 2003 00850 x ISSN 0085 2538 PMID 12631334 Cruzado Josep M Rico Jorge Grinyo Josep M April 2008 The renin angiotensin system blockade in kidney transplantation pros and cons Transplant International 21 4 304 313 doi 10 1111 j 1432 2277 2008 00638 x PMID 18266774 S2CID 24893488 a b Rossi S editor Australian Medicines Handbook 2006 Adelaide Australian Medicines Handbook 2006 ISBN 0 9757919 2 3 page needed a b c d e f g Sidorenkov G Navis G 2014 Safety of ACE inhibitor therapies in patients with chronic kidney disease Expert Opinion on Drug Safety 13 10 1383 1395 doi 10 1517 14740338 2014 951328 PMID 25148900 S2CID 207488068 a b Tucker Bryan M Perazella Mark A 2019 Medications 3 What are the major adverse effects on the kidney of ACE inhibitors and ARBs Nephrology Secrets Elsevier pp 78 83 doi 10 1016 b978 0 323 47871 7 00019 8 ISBN 978 0 323 47871 7 due to inhibition of angiotensin II production by ACE inhibitors or competitive antagonism of the angiotensin II receptor by ARBs results in loss of angiotensin II induced efferent arteriolar tone leading to a drop in glomerular filtration fraction and GFR The efferent arteriolal vasodilation reduces intraglomerular hypertension and pressure related injury and maintains perfusion and oxygenation of the peritubular capillaries a b c d Byrd James Brian Ram C Venkata S Lerma Edgar V 2019 Pharmacologic treatment of hypertension Nephrology Secrets Elsevier pp 477 482 doi 10 1016 b978 0 323 47871 7 00078 2 ISBN 978 0 323 47871 7 Angioedema 0 7 can also occur via pathobiology that remains obscure and its occurrence can be life threatening their efficacy is reduced by dietary or other sources of sodium and renal function may be further threatened if given with NSAIDs Thomas MC 2000 Diuretics ACE inhibitors and NSAIDs the triple whammy The Medical Journal of Australia 172 4 184 5 doi 10 5694 j 1326 5377 2000 tb125548 x PMID 10772593 S2CID 37558579 Cohn JN Kowey PR Whelton PK Prisant LM 2000 New guidelines for potassium replacement in clinical practice a contemporary review by the National Council on Potassium in Clinical Practice Archives of Internal Medicine 160 16 2429 36 doi 10 1001 archinte 160 16 2429 PMID 10979053 Okumura Hiromi Nishimura Eriko Kariya Satoru et al 1 March 2001 No Relation between Angiotensin Converting Enzyme ACE Inhibitor Induced Cough and ACE Gene Polymorphism Plasma Bradykinin Substance P and ACE Inhibitor Concentration in Japanese Patients Yakugaku Zasshi 121 3 253 257 doi 10 1248 yakushi 121 253 PMID 11265121 Vukadinovic D Vukadinovic AN Lavall D Laufs U Wagenpfeil S Bohm M March 2019 Rate of Cough During Treatment With Angiotensin Converting Enzyme Inhibitors A Meta Analysis of Randomized Placebo Controlled Trials Clinical Pharmacology and Therapeutics 105 3 652 660 doi 10 1002 cpt 1018 PMID 29330882 S2CID 46779755 Bezalel S Mahlab Guri K Asher I Werner B Sthoeger ZM February 2015 Angiotensin converting enzyme inhibitor induced angioedema The American Journal of Medicine 128 2 120 5 doi 10 1016 j amjmed 2014 07 011 PMID 25058867 Molinaro G Cugno M Perez M Lepage Y Gervais N Agostoni A Adam A 2002 Angiotensin converting enzyme inhibitor associated angioedema is characterized by a slower degradation of des arginine 9 bradykinin PDF The Journal of Pharmacology and Experimental Therapeutics 303 1 232 7 doi 10 1124 jpet 102 038067 hdl 2434 161106 PMID 12235256 S2CID 13866090 Augenstein VA Heniford BT Sing RF March 2013 Intestinal angioedema induced by angiotensin converting enzyme inhibitors an underrecognized cause of abdominal pain The Journal of the American Osteopathic Association 113 3 221 3 PMID 23485983 FDA Prescribing information http www rxmed com b main b2 pharmaceutical b2 1 monographs CPS 20Monographs CPS 20 28General 20Monographs 20A 29 ACE 20INHIBITORS html Sorensen AM Christensen S Jonassen TE Andersen D Petersen JS March 1998 Teratogenic effects of ACE inhibitors and angiotensin II receptor antagonists Ugeskrift for Laeger in Danish 160 10 1460 4 PMID 9520613 Bullo M Tschumi S Bucher BS Bianchetti MG Simonetti GD 2012 Pregnancy Outcome Following Exposure to Angiotensin Converting Enzyme Inhibitors or Angiotensin Receptor Antagonists A Systematic Review Hypertension 60 2 444 50 doi 10 1161 HYPERTENSIONAHA 112 196352 PMID 22753220 Cooper WO Hernandez Diaz S Arbogast PG Dudley JA Dyer S Gideon PS Hall K Ray WA 2006 Major congenital malformations after first trimester exposure to ACE inhibitors The New England Journal of Medicine 354 23 2443 2451 doi 10 1056 NEJMoa055202 PMID 16760444 ACE Inhibitors RxMed com Retrieved 2018 09 20 ACE I cvpharmacology a b ACEI contraindications Open Anesthesia Bakris GL Siomos M Richardson D Janssen I Bolton WK Hebert L Agarwal R Catanzaro D November 2000 ACE inhibition or angiotensin receptor blockade impact on potassium in renal failure VAL K Study Group Kidney International 58 5 2084 92 doi 10 1111 j 1523 1755 2000 00381 x PMID 11044229 Sear John W 2019 Antihypertensive Drugs and Vasodilators Pharmacology and Physiology for Anesthesia Elsevier pp 535 555 doi 10 1016 b978 0 323 48110 6 00026 0 ISBN 978 0 323 48110 6 S2CID 220688413 Coadministration of nonsteroidal anti inflammatory drugs NSAIDs cyclooxygenase inhibitors can reduce the hypotensive effects of ACE inhibitors ACE inhibitors can inhibit the excretion of lithium and can result in lithium toxicity Because these drugs do not affect the breakdown of kinins as is seen with the ACE inhibitors patients do not develop episodes of coughing and rarely develop angioneurotic edema Jandeleit Dahm K Cooper ME Sep 2006 Hypertension and diabetes role of the renin angiotensin system Endocrinol Metab Clin North Am 35 3 469 90 vii doi 10 1016 j ecl 2006 06 007 PMID 16959581 Wang W McKinnie SM Farhan M Paul M McDonald T McLean B Llorens Cortes C Hazra S Murray AG Vederas JC Oudit GY May 2016 Angiotensin Converting Enzyme 2 Metabolizes and Partially Inactivates Pyrapelin 13 and Apelin 17 Physiological Effects in the Cardiovascular System Hypertension 68 2 365 77 doi 10 1161 HYPERTENSIONAHA 115 06892 PMID 27217402 S2CID 829514 Human Physiology Silverthorn Pearson Benjamin Cummings 2004 page needed Ogbru O ACE Inhibitors Angiotensin Converting Enzyme Inhibitors MedicineNet com MedicineNet Inc Archived from the original on 26 March 2010 Retrieved 2010 03 20 a b c d Gradman Alan H Traub Darren 2007 Angiotensin Converting Enzyme Inhibitors Comprehensive Hypertension Elsevier pp 985 1001 doi 10 1016 b978 0 323 03961 1 50083 0 ISBN 978 0 323 03961 1 Despite the lack of long term suppression in plasma angiotensin II levels they maintain their BP lowering effect without the development of tolerance Importantly ACE inhibitors do not interfere with cognitive function or cardiovascular reflexes Hoogwerf BJ Young JB 2000 The HOPE study Ramipril lowered cardiovascular risk but vitamin E did not Cleveland Clinic Journal of Medicine 67 4 287 93 doi 10 3949 ccjm 67 4 287 PMID 10780101 Bicket Daphne P August 2002 Using ACE Inhibitors Appropriately American Family Physician 66 3 461 469 PMID 12182524 Retrieved 20 February 2019 Jerums G Allen T J Campbell D J Cooper M E Gilbert R E Hammond J J O Brien R C Raffaele J Tsalamandris C The Melbourne Diabetic Nephropathy Study Group November 2004 Long term renoprotection by perindopril or nifedipine in non hypertensive patients with Type 2 diabetes and microalbuminuria Diabetic Medicine 21 11 1192 1199 doi 10 1111 j 1464 5491 2004 01316 x ISSN 0742 3071 Strippoli Giovanni F M Craig Maria Deeks Jonathan J Schena Francesco Paolo Craig Jonathan C 2004 10 07 Effects of angiotensin converting enzyme inhibitors and angiotensin II receptor antagonists on mortality and renal outcomes in diabetic nephropathy systematic review BMJ 329 7470 828 doi 10 1136 bmj 38237 585000 7C ISSN 0959 8138 PMC 521570 PMID 15459003 Ajayi AA Campbell BC Howie CA Reid JL 1985 Acute and Chronic Effects of the Converting Enzyme Inhibitors Enalapril and Lisinopril on Reflex Control of Heart Rate in Normotensive Man Journal of Hypertension 3 1 47 53 doi 10 1097 00004872 198502000 00008 PMID 2987341 Adigun AQ Asiyanbola B Ajayi AA 2001 Cardiac autonomic function in Blacks with congestive heart failure vagomimetic action alteration in sympathovagal balance and the effect of ACE inhibition on central and peripheral vagal tone Cell Mol Biol Noisy le Grande 47 6 1063 7 PMID 11785658 verification needed Binkley PF Haas GJ Starling RC Nunziata E Hatton PA Leier CV Cody RJ 1 Mar 1993 Sustained augmentation of parasympathetic tone with angiotensin converting enzyme inhibition in patients with congestive heart failure J Am Coll Cardiol 21 3 655 61 doi 10 1016 0735 1097 93 90098 L PMID 8436747 Adigun AQ Ajayi AA 2001 The effects of enalapril digoxin diuretic combination therapy on nutritional and anthropometric indices in chronic congestive heart failure preliminary findings in cardiac cachexia European Journal of Heart Failure 3 3 359 63 doi 10 1016 S1388 9842 00 00146 X PMID 11378008 S2CID 31118266 Anker SD Ponikowski P Varney S Chua TP Clark AL Webb Peploe KM Harrington D Kox WJ Poole Wilson PA Coats AJ 1997 Wasting as independent risk factor for mortality in chronic heart failure The Lancet 349 9058 1050 3 doi 10 1016 S0140 6736 96 07015 8 PMID 9107242 S2CID 27285694 von Haehling S Morley JE Anker SD December 2010 An overview of sarcopenia facts and numbers on prevalence and clinical impact J Cachexia Sarcopenia Muscle 1 2 129 133 doi 10 1007 s13539 010 0014 2 PMC 3060646 PMID 21475695 Angiotensin Converting Enzyme ACE Inhibitors Cleveland Clinic Retrieved 2022 11 05 Lisinopril go drugbank com Retrieved 2022 11 05 a b c d Shibata Shigeru Fujita Toshiro 2018 Renin Angiotensin Aldosterone System Blockers Hypertension A Companion to Braunwald s Heart Disease Elsevier pp 230 241 doi 10 1016 b978 0 323 42973 3 00024 x ISBN 978 0 323 42973 3 ACE inhibitors are classified according to the chemical structure of the site of binding sulfhydryl phosphinyl carboxyl to the active center of ACE Kumar R Chaudhary K Sharma M Nagpal G Chauhan JS Singh S Gautam A Raghava GP 2015 AHTPDB a comprehensive platform for analysis and presentation of antihypertensive peptides Nucleic Acids Res 43 Database issue D956 62 doi 10 1093 nar gku1141 PMC 4383949 PMID 25392419 US4013791A Peptides having an antihypertensive effect Google Patents 1975 12 03 Retrieved 2020 03 21 FitzGerald RJ Murray BA Walsh DJ 2004 Hypotensive peptides from milk proteins The Journal of Nutrition 134 4 980S 8S doi 10 1093 jn 134 4 980S PMID 15051858 Aihara K Kajimoto O Hirata H Takahashi R Nakamura Y 2005 Effect of powdered fermented milk with Lactobacillus helveticus on subjects with high normal blood pressure or mild hypertension Journal of the American College of Nutrition 24 4 257 65 doi 10 1080 07315724 2005 10719473 PMID 16093403 S2CID 18513821 a b Boelsma E Kloek J 2009 Lactotripeptides and 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2005 The reno protective effect of the dual blockade of the renin angiotensin system RAS Current Pharmaceutical Design 11 10 1291 300 doi 10 2174 1381612053507413 PMID 15853685 van de Wal RM van Veldhuisen DJ van Gilst WH Voors AA 2005 Addition of an angiotensin receptor blocker to full dose ACE inhibition controversial or common sense European Heart Journal 26 22 2361 7 doi 10 1093 eurheartj ehi454 PMID 16105846 ONTARGET Investigators Yusuf S Teo KK Pogue J Dyal L Copland I Schumacher H Dagenais G Sleight P Anderson C 10 April 2008 Telmisartan ramipril or both in patients at high risk for vascular events PDF The New England Journal of Medicine 358 15 1547 59 doi 10 1056 NEJMoa0801317 hdl 2437 81925 PMID 18378520 Archived PDF from the original on 2022 10 09 Finnegan PM Gleason BL 2003 Combination ACE inhibitors and angiotensin II receptor blockers for hypertension Annals of Pharmacotherapy 37 6 886 9 doi 10 1345 aph 1C393 PMID 12773079 S2CID 25509704 Shelley Wood 11 April 2014 EMA Don t Combine ARBs ACE Inhibitors and Direct Renin Inhibitors www medscape com Krum H Carson P Farsang C Maggioni AP Glazer RD Aknay N Chiang YT Cohn JN 2004 Effect of valsartan added to background ACE inhibitor therapy in patients with heart failure results from Val HeFT European Journal of Heart Failure 6 7 937 45 doi 10 1016 j ejheart 2004 09 005 PMID 15556056 S2CID 40739892 Solomon SD Skali H Anavekar NS Bourgoun M Barvik S Ghali JK Warnica JW Khrakovskaya M Arnold JM Schwartz Y Velazquez EJ Califf RM McMurray JV Pfeffer MA 2005 Changes in Ventricular Size and Function in Patients Treated with Valsartan Captopril or Both After Myocardial Infarction Circulation 111 25 3411 3419 doi 10 1161 CIRCULATIONAHA 104 508093 PMID 15967846 Yang Y Ohta K Shimizu M Nakai A Kasahara Y Yachie A Koizumi S Jul 2005 Treatment with low dose angiotensin converting enzyme inhibitor ACEI plus angiotensin II receptor blocker ARB in pediatric patients with IgA nephropathy Clinical Nephrology 64 1 35 40 doi 10 5414 CNP64035 PMID 16047643 Bernstein Kenneth E Ong Frank S Blackwell Wendell Lamar B Shah Kandarp H Giani Jorge F Gonzalez Villalobos Romer A Shen Xiao Z Fuchs Sebastien January 2013 A Modern Understanding of the Traditional and Nontraditional Biological Functions of Angiotensin Converting Enzyme Pharmacological Reviews 65 1 1 46 doi 10 1124 pr 112 006809 ISSN 0031 6997 PMC 3565918 PMID 23257181 Myat Aung Gershlick A H Gershlick Tony 2012 17 Systemic arterial hypertension Landmark Papers in Cardiovascular Medicine Oxford Oxford University Press pp 2286 287 ISBN 978 0 19 959476 4 LCCN 2012940771 Ferreira SH February 1965 A bradykinin potentiating factor bpf present in the venom of bothrops jararaca Br J Pharmacol Chemother 24 1 163 9 doi 10 1111 j 1476 5381 1965 tb02091 x PMC 1704050 PMID 14302350 Ng KK Vane JR 1967 Conversion of Angiotensin I to Angiotensin II Nature 216 5117 762 6 Bibcode 1967Natur 216 762N doi 10 1038 216762a0 PMID 4294626 S2CID 4289093 Ng KK Vane JR 1968 Fate of Angiotensin I in the Circulation Nature 218 5137 144 50 Bibcode 1968Natur 218 144N doi 10 1038 218144a0 PMID 4296306 S2CID 4174541 Ng KK Vane JR 1970 Some Properties of Angiotensin Converting Enzyme in the Lung in vivo Nature 225 5238 1142 4 Bibcode 1970Natur 225 1142N doi 10 1038 2251142b0 PMID 4313869 S2CID 4200012 Cushman D W Ondetti M A 1991 History of the design of captopril and related inhibitors of angiotensin converting enzyme Hypertension 17 4 589 592 doi 10 1161 01 HYP 17 4 589 PMID 2013486 S2CID 30766421 Drugs FDA FDA Approved Drugs www accessdata fda gov Retrieved 2023 09 29 Drugs FDA FDA Approved Drugs www accessdata fda gov Retrieved 2023 09 29 Bicket Daphne P 2002 08 01 Using ACE Inhibitors Appropriately American Family Physician 66 3 461 469 Hata Y Yamamoto M Ohni M Nakajima K Nakamura Y Takano T 1996 A placebo controlled study of the effect of sour milk on blood pressure in hypertensive subjects The American Journal of Clinical Nutrition 64 5 767 71 doi 10 1093 ajcn 64 5 767 PMID 8901799 Nakamura Y Yamamoto N Sakai K Takano T 1995 Antihypertensive effect of sour milk and peptides isolated from it that are inhibitors to angiotensin I converting enzyme Journal of Dairy Science 78 6 1253 7 doi 10 3168 jds S0022 0302 95 76745 5 PMID 7673515 External links edit nbsp Wikimedia Commons has media related to ACE inhibitors From snake venom to ACE inhibitor the discovery and rise of captopril Retrieved from https en wikipedia org w index php title ACE inhibitor amp oldid 1187011541, wikipedia, wiki, book, books, library,

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