What is chloroquine mechanism of action uses and side effects
Chloroquine is a synthetic drug mainly used for the treatment of malaria. Chloroquine was discovered in 1934, it started to practice for the medical needs in the 1940s. It is one of the quinoline derivatives and a member of chemically related antimalarial agents. This chloroquine is tearmed chloroquine phosphate. chloroquine hydrochloride can also use as an intramuscular injection. Chloroquine and hydroxychloroquine are closely related to each other. This is another derivative of quinoline. Hydroxychloroquine can also be used for treating inflammatory rheumatic diseases and malaria.
Chloroquine Chemical Structure
The chemical formula for Chloroquine is C₁₈H₂₆ClN₃. The chloroquine chemical structure 7-chloro-4-(4-diethylamino-1-methyl butyl amino)-quinoline, is formed while 4,7-di chloroquinoline is reacted with 4-diethylamino-1-methyl butylamine at 180 °C.
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This image shows the chloroquine structure and IUPAC name.
Mechanism of Chloroquine
The chloroquine has a lysosomotropic character, which helps to perform as an antimalarial drug. Chloroquine drug concentrates on acidic food vacuole of the parasite and enters into the essential process. The lysosomotropic properties allow it for the use of in vitro experiments pertaining to intracellular lipid-related disease namely apoptosis and autophagy.
The malarial parasite present in the red blood cells undergoes an asexual lifecycle. It starts affecting the hemoglobin to acquire essential amino acids. As the parasite requires to build its own protein and energy metabolism. The digestion of the parasites carries out in a vacuole of the cells. Hemoglobin composed of protein unit and heme unit. The parasite can digest protein units but cannot synthesize heme units. During the digestion process, parasites release the toxic, soluble molecule heme unit. This heme unit consists of the porphyrin ring called Fe(II)-protoporphyrin IX (FP). To avoid destruction by this molecule, hemozoin is formed by the parasite biocrystallizes heme. Hemozoin gets stored in a digestive vacuole as insoluble crystals.
Chloroquine entering the red blood cells. It inhibits the parasite cell and digestive vacuole for the diffusion process. Chloroquine transfers CQ2+ protons as the digestive vacuole is acidic. So, the parasite cannot go for the diffusion process. Chloroquine covers hemozoin molecules to prevent further biocrystallization of heme thus helps to heme buildup.
The chloroquine join to heme to form the FP-chloroquine complex. This gets high toxic to the cell and disturbs the membrane function. The action of the toxic FP and FP- chloroquine results in cell lysis and supports parasite cell autodigestion. If the parasite does not form hemozoin, then it is resistant to chloroquine.
P. falciparum is a resistant strains of chloroquine. These strains are showing resistant behaviour to chloroquine this is because mainly due to the evolution of species. It was discovered in East and West Africa, Southeast Asia, and South America. The resistant parasites use its transmembrane pump to remove chloroquine from the digestive vacuole. These chloroquine-resistant parasites pump out 40 times more than the chloroquine-sensitive parasites. P. falciparum codes the pump by the chloroquine resistance transporter (PfCRT) gene. The main function of the chloroquine pump is to transport peptides. A Ca²⁺ channel blocker Verapamil has found to restore the ability of chloroquine to treat resistance parasites.
Chloroquine Uses
Chloroquine is an effective agent to act against the susceptible strains of malarial parasites Plasmodium ovale, Plasmodium vivax, and Plasmodium falciparum and some parasitic worms and amoebas. It can also be used for the treatment of inflammatory rheumatic diseases namely rheumatoid arthritis and lupus erythematosus.
Chloroquine Side Effects
Chloroquine tablet uses brings some side effects. The chloroquine side effects vary depends on the individual’s immune power. Chloroquine phosphate uses have mild side effects like abdominal cramps and headache, it is a common effect of all antimalarial drugs. They may also experience tinnitus, skin rashes, nausea, vomiting, muscle weakness, visual impairment, and changes in behaviour. Visual impairment is mainly due to retinal damage. This may occur only due to the long-term chloroquine phosphate uses. This condition of experiencing visual impairment is known as chloroquine retinopathy.
This chloroquine will interact with other medications namely, antibiotics like ampicillin, erythromycin, antacids, antiarrhythmics which increases side effects. Drug-to-drug interactions will alter the chloroquine interaction level in the body. It may block the chloroquine metabolism, which results in toxic chloroquine accumulation in the body. Also, chloroquine has the potential to alter the level of other drugs. This increases the toxicity of the agent and the risk of side effects. A similar derivative of quinoline, hydroxychloroquine has many side effects as chloroquine. But, it is comparatively less toxic.
How to Use Chloroquine Phosphate?
Chloroquine phosphate can intake in the form of tablets. Chloroquine tablet uses for treating malaria and amebiasis. To prevent malaria in adults, can use one dose of the tablet for one week. That should take on the same day of the week. The dosage level must be determined by the doctors. It is preferable to take one dose of chloroquine hydrochloride before 2 weeks or after 8 weeks for travelling to the malaria-affected areas. If a person severely affected by malaria, the physician will prefer to take an extra half a dose after 6 to 8 hours of taking one dose of tablets. For treating or preventing children from malaria, physicians calculate the amount of chloroquine phosphate level based on children’s weight.
For treating amebiasis, it is recommended to take one dose of tablets for 2 days and a half dose of tablets every 2 to 3 weeks. chloroquine tablet can be taken with other amebicides medicine.
FAQs on Chloroquine Drug Profile in Biology and Medicine
1. What is chloroquine and what is it used for?
Chloroquine is an antimalarial drug used to prevent and treat infections caused by Plasmodium parasites. It is primarily prescribed for:
- Treatment and prevention of malaria
- Management of autoimmune diseases such as rheumatoid arthritis
- Treatment of systemic lupus erythematosus (SLE)
2. How does chloroquine work against malaria?
Chloroquine kills malaria parasites by disrupting heme detoxification inside infected red blood cells. During infection:
- The Plasmodium parasite digests hemoglobin for nutrition.
- This releases toxic heme molecules.
- The parasite normally converts heme into non-toxic hemozoin.
- Chloroquine blocks this conversion, causing toxic heme to accumulate.
3. What type of malaria can chloroquine treat?
Chloroquine is effective against chloroquine-sensitive strains of malaria, particularly Plasmodium vivax, Plasmodium ovale, and Plasmodium malariae. It may also treat Plasmodium falciparum in regions where resistance has not developed. However, many P. falciparum strains worldwide are now chloroquine-resistant.
4. What is chloroquine resistance in malaria?
Chloroquine resistance occurs when Plasmodium falciparum develops the ability to survive despite chloroquine treatment. This resistance is mainly due to:
- Mutations in the PfCRT gene (Plasmodium falciparum chloroquine resistance transporter)
- Reduced accumulation of chloroquine inside the parasite’s food vacuole
5. What is the difference between chloroquine and hydroxychloroquine?
The main difference between chloroquine and hydroxychloroquine is that hydroxychloroquine has an added hydroxyl group, making it less toxic and better tolerated. Key differences include:
- Hydroxychloroquine has lower risk of severe side effects.
- Both are used for malaria and autoimmune diseases.
- Hydroxychloroquine is more commonly prescribed for long-term autoimmune therapy.
6. How does chloroquine affect the immune system?
Chloroquine modulates the immune system by reducing inflammatory responses and interfering with antigen processing. It works by:
- Increasing the pH of lysosomes in immune cells
- Reducing activation of T cells
- Decreasing production of inflammatory cytokines
7. What are the side effects of chloroquine?
Chloroquine can cause mild to serious side effects, especially with long-term use. Common and important side effects include:
- Nausea and gastrointestinal discomfort
- Headache and dizziness
- Retinopathy (damage to the retina) with prolonged use
- Cardiac effects such as QT interval prolongation
8. Why is chloroquine less effective in some regions?
Chloroquine is less effective in some regions due to widespread drug-resistant Plasmodium falciparum strains. Resistance developed because:
- Extensive and prolonged use of chloroquine exerted selective pressure.
- Genetic mutations allowed parasites to pump the drug out of their food vacuoles.
9. Can chloroquine be used to prevent malaria?
Chloroquine can be used for malaria prevention in areas where the parasite remains chloroquine-sensitive. For prophylaxis:
- It is taken before entering a malaria-endemic area.
- Continued during the stay.
- Maintained for several weeks after leaving the area.
10. How is chloroquine absorbed and distributed in the body?
Chloroquine is well absorbed orally and widely distributed throughout body tissues. Key pharmacological features include:
- Rapid absorption from the gastrointestinal tract
- Accumulation in organs such as the liver, spleen, kidneys, and retina
- Long half-life due to extensive tissue binding
