Angiotensin II Receptor Blockers (ARBs): Indications, Mechanism of Action, Side Effects

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What Are Angiotensin II Receptor Blockers (ARBs)?

Angiotensin II receptor blockers or antagonists (ARBs) are a class of medications commonly used as antihypertensive drugs to treat hypertension or high blood pressure.

ARBs also have indications for various cardiac and renal diseases such as heart failure and diabetic nephropathy.

We will discuss the mechanism of action (MOA) and how ARBs work to lower blood pressure, along with their side effects, other indications, and contraindications.

A list of example ARBs will be provided along with tricks to remember them all, including how their drug names typically end in “sartan” (losartan, valsartan, etc.).

The renin-angiotensin-aldosterone system will also be reviewed as ARBs inhibit the normal physiology by primarily blocking angiotensin II type 1 receptors (AT1) located on blood vessels and the kidneys.

The below “Antihypertensive Chart” was used in a previous EZmed lecture in which ACE inhibitors, ARBs, alpha blockers, beta blockers, calcium channel blockers, and diuretics were all compared to one another.

Although the chart provided a broad overview of the main antihypertensive drugs, we will now focus solely on the pharmacology of ARBs.

Let’s get started!

How Do Angiotensin II Receptor Blockers (ARBs) Work?

In order to better understand how ARBs work, we need to know what angiotensin II is. 

Angiotensin II plays an important role in the renin-angiotensin-aldosterone system. 

Let’s quickly review the renin-angiotensin-aldosterone system (RAAS) as the mechanism of action for ARBs will become more clear.

If you already viewed the ACE inhibitor post, then this should look familiar and be a good review.

Renin Release

The RAAS is important in regulating blood pressure and blood volume, especially when blood pressure is low.

The kidneys detect whenever there is decreased blood flow or blood volume present, and they panic out of concern they are not receiving enough blood.

As a result, the kidneys release an enzyme called renin which is the first step of the RAAS.

Specifically it is the juxtaglomerular cells (JG cells) of the kidneys that secrete renin. 

You can think of RENin and RENal to help you remember renin is released by the kidneys. 

The sympathetic nervous system can also activate the JG cells to release renin. 

The sympathetic nervous system is involved in our fight or flight response.

One of those responses is to increase blood pressure in order to better perfuse vital tissues and organs during a stressful or dangerous situation.

Therefore, it makes sense the sympathetic nervous system can activate the RAAS in order to help increase blood pressure.

Sympathetic catecholamines such as epinephrine and norepinephrine activate beta-1 receptors located on JG cells, thereby causing renin release.

Lastly, decreased sodium levels in the distal tubule of the nephron can stimulate renin release as well.

Whenever there is decreased blood pressure or perfusion to the kidneys, then there will be increased sodium and water reabsorption at the proximal tubule of the nephron in order to increase blood pressure.

As a result, there will be decreased sodium levels in the distal tubule because much of the sodium has already been reabsorbed back into the bloodstream.

The macula densa cells of the distal tubule detect the decreased sodium levels, and they stimulate the JG cells to release renin in order to increase blood pressure more.

Likewise, hyponatremia (decreased sodium levels in the blood) can also stimulate renin release.

Angiotensinogen to Angiotensin I

Once renin is released by the kidneys, it converts angiotensinogen into angiotensin I.

Angiotensinogen is a protein produced by the liver.

You can use the “GIN” in angiotensinogen to think of alcohol, and alcohol is metabolized by the liver.

This will help you remember angiotensinogen is produced by the liver. 

Renin is an enzyme that cleaves angiotensinogen to form angiotensin I. 

Angiotensin I to Angiotensin II

Angiotensin II is the active peptide hormone we need, not angiotensin I.

Angiotensin I is simply the inactive precursor for angiotensin II, so we need to convert the inactive form into the active one.

We accomplish this through another enzyme called angiotensin-converting enzyme (ACE), which is primarily located in the endothelium of blood vessels in the lungs.

You can associate ACE with AIR, and this will help you remember ACE is primarily found in the lungs. 

As the name suggests, angiotensin-converting enzyme converts angiotensin I into angiotensin II.

Angiotensin II then has multiple effects on the body to increase blood pressure. 

Remember we said the RAAS is activated by decreased renal perfusion, so it makes sense the goal of the RAAS would be to increase blood pressure in order to better perfuse the kidneys. 

What is the Role of Angiotensin II?

Now that we know how angiotensin II is produced by the RAAS, let’s review the effects angiotensin II has on the body.

Understanding angiotensin II will help us figure out how ARBs work.

If you already checked out the ACE inhibitor post, this should be a good review.

Angiotensin II has several mechanisms to increase blood pressure:

1. Vasoconstriction

2. Sodium/Water Reabsorption

3. Aldosterone Release

4. Antidiuretic Hormone Release

5. Sympathetic Augmentation/Adrenal Medulla Stimulation

Blood Pressure Equation

Here is a quick reminder of the blood pressure equation as its variables will be referenced below when discussing the effects of angiotensin II.

1. Vasoconstriction

First, angiotensin II is a potent vasoconstrictor. 

There are angiotensin II receptors located on the smooth muscle cells of blood vessels. 

Just so you are aware, there are 2 main types of angiotensin II receptors - type I (AT1) and type 2 (AT2).

It is mainly type 1 we are referring to as we discuss the angiotensin II receptors.

When angiotensin II binds to these receptors, it causes vascular smooth muscle contraction.

Vascular smooth muscle contraction leads to increased vasoconstriction. 

If we reduce the diameter of a blood vessel, then systemic vascular resistance increases.

Systemic vascular resistance (SVR) is also known as total peripheral resistance (TPR).

As we can see from the blood pressure equation above, increasing SVR will increase blood pressure.

2. Sodium/Water Reabsorption

Angiotensin II also affects the kidneys. 

First, it can directly stimulate sodium and water reabsorption at the proximal tubule of the nephron. 

If we reabsorb sodium and water from the kidney back into the bloodstream, then blood volume will increase. 

An increase in blood volume will increase stroke volume, which will increase cardiac output. 

As we can see from the blood pressure equation above, an increase in stroke volume will increase blood pressure. 

3. Aldosterone Release

Angiotensin II can also stimulate the release of aldosterone from the adrenal cortex. 

Aldosterone is a hormone that primarily acts on the distal tubule of the nephron to increase sodium and water reabsorption. 

This will then have the same downstream effects of increasing blood volume, stroke volume, and blood pressure that we saw before. 

Aldosterone also increases potassium excretion in the urine, which will become important when we talk about the side effects and contraindications of ARBs. 

4. Antidiuretic Hormone Release

Angiotensin II also stimulates the release of antidiuretic hormone from the posterior pituitary gland. 

Antidiuretic hormone (ADH) is also known as vasopressin. 

ADH acts on the collecting duct of the nephron to facilitate water reabsorption. 

As we saw above, water reabsorption will increase blood volume, which will increase stroke volume, which will increase blood pressure. 

There are also vasopressin receptors located on the smooth muscle cells of blood vessels.

Activation of these receptors by ADH/vasopressin will cause vascular smooth muscle contraction. 

As we saw above, vascular smooth muscle contraction leads to increased vasoconstriction, increased SVR, and increased blood pressure. 

5. Sympathetic Augmentation/Adrenal Medulla Stimulation

As mentioned above, the sympathetic nervous system can help activate the RAAS by stimulating the JG cells to release renin.

Angiotensin II can then go back and affect the sympathetic nervous system by augmenting sympathetic outflow centrally. 

Angiotensin II can also stimulate the adrenal medulla to secrete epinephrine and norepinephrine, which are the main catecholamines of the sympathetic nervous system. 

So we can see how the effects of angiotensin II connect together, and how angiotensin II has multiple mechanisms to increase blood pressure. 

What is the Mechanism of Action of ARBs?

Now that we understand the RAAS and the effects of angiotensin II, let’s review how ARBs work. 

As the name suggests, angiotensin II receptor blockers block angiotensin II receptors.

In other words, ARBs are angiotensin II receptor antagonists.

We now know angiotensin II plays an important role in blood pressure regulation, especially to increase blood pressure.

If we block angiotensin II receptors, then we will decrease the effects of angiotensin II.

The decrease in angiotensin II effects will lead to a decrease in blood pressure. 

What Are the Effects of ARBs?

Blocking angiotensin II receptors with an ARB will have multiple effects on the body, similar to what we saw with ACE inhibitors.

Simply put, all of the angiotensin II effects we discussed above will be inhibited or reduced by ARBs.

Knowing these effects will help us understand the indications for ARBs.

1. Decreased Vasoconstriction

2. Decreased Sodium/Water Reabsorption

3. Decreased Aldosterone Release

4. Decreased Antidiuretic Hormone Release

5. Decreased Sympathetic Augmentation/Adrenal Medulla Stimulation

1. Decreased Vasoconstriction

Angiotensin II normally binds to angiotensin II receptors on blood vessels, which causes smooth muscle contraction and vasoconstriction. 

By blocking angiotensin II receptors with an ARB, we will have less vascular smooth muscle contraction and less vasoconstriction. 

Less vasoconstriction means the blood vessels have a larger diameter, which will decrease systemic vascular resistance. 

Decreased systemic vascular resistance leads to a decrease in blood pressure.

2. Decreased Sodium/Water Reabsorption

Normally angiotensin II increases sodium and water reabsorption in the proximal tubule of the nephron.

Blocking angiotensin II receptors with an ARB means less sodium and water reabsorption, which will decrease blood volume, which will decrease stroke volume, which will decrease blood pressure. 

3. Decreased Aldosterone Release

We also know angiotensin II stimulates aldosterone secretion from the adrenal cortex.

Blocking angiotensin II receptors with an ARB will lead to less aldosterone release, which means less sodium and water reabsorption in the distal tubule of the nephron. 

This too will decrease blood volume, stroke volume, and blood pressure. 

Remember we also said aldosterone increases potassium excretion in the urine.

With less aldosterone, there will be less potassium excretion which means more potassium in the serum.

This will become important in a bit when we talk about the side effects and contraindications of ARBs. 

4. Decreased Antidiuretic Hormone Release

We also know angiotensin II increases the release of antidiuretic hormone (ADH) from the posterior pituitary gland. 

By blocking angiotensin II receptors with an ARB, we will have less ADH release. 

As a result, there will be less water reabsorption in the collecting duct of the nephron, which will lead to decreased blood volume, stroke volume, and blood pressure. 

With lower levels of ADH (also known as vasopressin), there will also be less binding to vasopressin receptors on blood vessels.

This will lead to decreased smooth muscle contraction, decreased vasoconstriction, decreased systemic vascular resistance, and decreased blood pressure. 

5. Decreased Sympathetic Augmentation/Adrenal Medulla Stimulation

We also know angiotensin II augments sympathetic outflow centrally and stimulates the adrenal medulla to secrete epinephrine and norepinephrine. 

Blocking angiotensin II receptors with an ARB will decrease sympathetic outflow augmentation and decrease the stimulation of the adrenal medulla. 

“ARB” Mnemonic

The main effects of ARBs can be remembered using the mnemonic “ARB”.

A

ARBs block the effects of angiotensin II, as well as decrease the levels of aldosterone and antidiuretic hormone, all of which can be remembered using the letter “A”.

R

ARBs decrease systemic vascular resistance, which can be remembered using the “R” for resistance.

B

ARBs decrease blood volume, which can be remembered using the “B” for blood volume.

Examples of ARBs

Let’s take a look at example angiotensin II receptor blockers.

The easy way to remember ARBs is their drug names usually end with the suffix “sartan”. 

Examples include losartan, valsartan, candesartan, eprosartan, and olmesartan.

Indications for ARBs

Now that we understand the mechanism of action of angiotensin II receptor blockers, let’s go over their indications. 

ARBs have 2 major effects on the body as we saw above:

1. They decrease vasoconstriction by blocking angiotensin II receptors on blood vessels and decreasing the release of ADH/vasopressin (which would normally bind to blood vessels as well).

2. They decrease sodium/water reabsorption by blocking angiotensin II receptors in the proximal tubule of the nephron, and by decreasing the release of ADH and aldosterone.

Decreased vasoconstriction and decreased sodium/water reabsorption are 2 of the main underlying mechanisms in which ARBs treat various conditions.

Similar to ACE inhibitors, ARBs can be used in:

1. Hypertension

2. Heart Failure

3. Coronary Artery Disease/Post-Myocardial Infarction

4. Cardiac Remodeling

5. Renal Disease

1. Hypertension

We know decreasing vasoconstriction will decrease systemic vascular resistance (SVR).

We also know decreasing sodium/water reabsorption will decrease blood volume, which will decrease stroke volume, which will decrease cardiac output (CO). 

Remember our equation for blood pressure was CO x SVR, with cardiac output equaling heart rate x stroke volume. 

So it should be no surprise that if we decrease systemic vascular resistance and cardiac output, then we will decrease blood pressure. 

This is why ARBs can be used to treat hypertension (high blood pressure).

2. Heart Failure

ARBs are also indicated for heart failure as they can decrease afterload and preload.

Afterload

Another way to think of systemic vascular resistance is afterload.  

Afterload is the amount of resistance the heart must overcome in order to pump blood forward into the vasculature.

So if we decrease systemic vascular resistance using ARBs, then afterload decreases because the heart does not have to work as hard to pump blood forward. 

Preload

Similarly, another way to think of blood volume is preload. 

Preload is the amount of stretch on the heart before contraction, which is influenced by the volume of blood returning to the heart. 

So if we decrease blood volume using ARBs, then preload decreases because there is less venous pressure and blood return to the heart.

Furthermore, vasodilation from ARBs can dilate the veins. This can further reduce preload by decreasing venous pressure and blood return to the heart. 

Afterload and Preload

By collectively reducing afterload and preload with ARBs, we decrease the amount of stress and work on the heart.

This will also decrease the oxygen demand on the heart. 

As a result, ARBs can be used in heart failure when the heart is already weak and will perform better under less stress. 

Decreasing the afterload helps improve ejection fraction in heart failure because there is less resistance the heart must overcome. 

Reducing preload can help decrease the pulmonary/systemic congestion and edema seen in heart failure because there is less venous pressure. 

3. Coronary Artery Disease/Post-Myocardial Infarction

Reducing afterload and preload decreases the oxygen demand on the heart as we saw above.

This is not only beneficial in heart failure, but also in coronary artery disease (CAD) or after a myocardial infarction (MI) when it is important to limit the oxygen demand and stress on the heart. 

As a result, ARBs are commonly indicated in CAD or after an MI. 

4. Cardiac Remodeling

Chronic hypertension, heart failure, coronary artery disease, or a recent myocardial infarction can all lead to changes in the size and shape of the heart, called cardiac remodeling.

Cardiac remodeling can result in decreased pumping function of the heart. 

ARBs can prevent cardiac remodeling by decreasing afterload, preload, and overall stress on the heart. 

5. Renal Disease

Finally, ARBs can be used to reduce the progression of renal disease from chronic diabetes or hypertension, called diabetic nephropathy and hypertensive nephropathy.

Chronic hypertension and diabetes can progressively damage the kidney leading to proteinuria, worsening renal function, and development of chronic kidney disease.

Inhibiting the renin-angiotensin-aldosterone system with ARBs has been shown to protect the kidneys and slow the progression of renal disease.

ACE Inhibitors vs ARBs

ARBs and ACE inhibitors have many of the same indications, which makes sense because their mechanism of action is similar.

They both decrease the effects of the renin-angiotensin-aldosterone system (RAAS).

However, there are a couple indications for ARBs that differentiate them from ACE inhibitors:

1. ACE Inhibitor Induced Cough

2. ACE Inhibitor Induced Angioedema

ACE Inhibitor Induced Cough and Angioedema

You might remember from the ACE inhibitor lecture that ACE inhibitors can cause cough and angioedema. 

Cough and angioedema are mainly caused by increased bradykinin levels. 

Bradykinin is a peptide with a couple effects on the body. 

First, it can cause bronchoconstriction in the lungs which can lead to a cough. 

Second, bradykinin is involved in inflammation and can cause vasodilation, increased vascular permeability (which can increase edema), and increased pain perception. 

So how do ACE inhibitors play a role?

Angiotensin-converting enzyme (ACE) normally degrades bradykinin, which would lead to a decrease in bradykinin levels. 

This makes sense as the goal of the RAAS is to increase blood pressure, and bradykinin causes vasodilation which would be counterproductive. 

If we block ACE with an ACE inhibitor, then we will have less bradykinin degradation which will result in higher levels of bradykinin. 

This can cause increased cough and increased edema, known as angioedema.

ARBs and Bradykinin

Since angiotensin II receptor blockers do not involve ACE, bradykinin levels are not impacted as much compared to ACE inhibitors.

There is decreased incidence of cough and angioedema with ARBs compared to ACE inhibitors as a result.

Of note, there have been rare cases of angioedema with ARBs and cross-reactivity between ACE inhibitors and ARBs is possible.

So if a patient has angioedema or cough from an ACE inhibitor, then the provider and patient will have to decide the risk and benefit of switching to an ARB versus a different class depending on the condition being treated. 

Side Effects of ARBs

Now that we know the indications for ARBs, let’s review their side effects.

You can use the mnemonic “LOSARTAN” (which is a type of ARB) to remember the main side effects.

“LOSARTAN” stands for low blood pressure, other (fatigue, headache, dizziness), swelling, allergic reaction, raised potassium, teratogenic, acute kidney injury, and nasal congestion.

Low Blood Pressure (Hypotension)

The first side effect is low blood pressure, which makes sense because ARBs are used to treat hypertension. 

This is especially true when first starting an ARB or if a patient is already taking multiple medications for their hypertension.

It is important to monitor blood pressure as a result.

Other (Fatigue, Headache, Dizziness)

ARBs can also cause general mild to moderate symptoms including fatigue, headache, and dizziness to name a few. 

Swelling

ARBs can cause swelling to the hands and feet, especially if an acute kidney injury develops from taking an ARB (more on this below).

Swelling should also remind you of angioedema.

Again, angioedema is associated more with ACE inhibitors because of bradykinin, but there are rare cases of ARBs causing it too. 

Allergic Reaction

Although fairly uncommon, allergic reactions can develop from taking an ARB.

Reactions are usually mild such as a rash, but more severe ones could occur.

Raised Potassium (Hyperkalemia)

ARBs can raise serum potassium levels, known as hyperkalemia. 

Remember we said angiotensin II stimulates aldosterone release, and aldosterone increases potassium excretion in the urine.

Increased potassium excretion results in lower levels of potassium in the blood.

If we block aldosterone release with an ARB, then there will be less potassium excreted in the urine which will mean more potassium in the blood.

Hyperkalemia may be present as a result. 

Teratogenic

ARBs have also been shown to be teratogenic and should be avoided during pregnancy.

Acute Kidney Injury

Another side effect is acute kidney injury, especially when first starting an ARB.

We said earlier that ARBs are renal-protective and slow the progression of renal disease. 

However, if a patient already has an underlying condition causing poor renal perfusion, such as chronic kidney disease, polycystic kidney disease, or renal artery stenosis, then ARBs could be detrimental by decreasing renal perfusion even more.

Therefore, it is important to monitor renal function closely when first starting an ARB, especially if an underlying kidney disease is already present.

Nasal Congestion

ARBs can cause side effects to the upper airway, sinuses, and nasopharynx including nasal congestion and drainage.

Contraindications of ARBs

Let’s wrap this up with contraindications of ARBs, most of which can be pieced together from the side effects and pathophysiology already discussed. 

Antihypertensives

Although not a major contraindication, be mindful if the patient is already taking other antihypertensive medications as adding an ARB could cause hypotension, orthostatic hypotension, dizziness, lightheadedness, or syncope. 

Angioedema/Anaphylaxis

If a patient has a prior history of angioedema or anaphylaxis from an ARB, then ARBs should be avoided. 

If a patient had angioedema or anaphylaxis from an ACE inhibitor, use caution and careful consideration when thinking about switching to an ARB. 

Remember there are rare cases of angioedema with an ARB, and there is the possibility of cross-reactivity between ACE inhibitors and ARBs. 

Hyperkalemia

Another contraindication, or at least a relative one in some circumstances, is hyperkalemia.

This is particularly true if the patient is taking other medications that can raise potassium levels, or they have a diet rich in potassium, or have any other risk factors for developing hyperkalemia. 

As we know from above, ARBs can cause hyperkalemia by decreasing aldosterone levels.

Pregnancy

As mentioned before, ARBs can be teratogenic and should be avoided during pregnancy. 

Bilateral Renal Artery Stenosis

We also mentioned ARBs can lead to worsening renal function in a patient with underlying kidney disease and poor renal perfusion at baseline. 

This is particularly true in patients with bilateral renal artery stenosis, in which perfusion to the kidneys is already limited. 

Giving an ARB to a patient with bilateral renal artery stenosis could decrease what little perfusion to the kidneys they already have, and could make their renal function worse. 

Caution and close monitoring should also be used in anyone with underlying chronic kidney disease (CKD).

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