Q1: How is Malaria Diagnosed and Treated?
Q1: How is Malaria Diagnosed and Treated?
Ans: Early diagnosis and treatment of malaria reduces disease and prevents deaths. It also contributes to reducing malaria transmission. The best available treatment, particularly for P. falciparum malaria, is artemisinin-based combination therapy (ACT). The WHO recommends that all cases of suspected malaria should be confirmed using parasite-based diagnostic testing. This can either be microscopy or via a rapid diagnostic test. Afterwards, treatment can start based on the type of malaria. Results of parasitological confirmation are generally available in 30 minutes or less. The treatment is based on symptoms and should only be considered when a parasitological diagnosis is not possible.
Ans: Once the malarial parasite matures it ruptures the liver cells and enters back into the bloodstream. Once in the bloodstream the parasite infects RBCs with a toxin call haemazoin which ruptures the blood cell and also cause a condition known as the chills. The chills are the first stage of the malaria fever.
Q3: Malaria is Caused by Which Mosquito?
Ans: The malaria disease is caused by the female anopheles mosquito which is the carrier for the plasmodium parasite.
Q4: What are the Main Symptoms of Malaria?
Ans: Please have a look at the malaria symptoms section.
Q5: What are the Causes, Symptoms and Prevention of Malaria?
Ans: Please go through the topic above.
Q6: Explain Any Two Methods of Prevention Against Malaria.
Ans: Please have a look at the prevention of malaria section.
Malaria Definition: Malaria is a life-threatening disease that is transmitted through the bite of an infected female Anopheles mosquito. Infected mosquitoes carry the Plasmodium parasite (the malarial parasite/ the causative agent of malaria). When this mosquito bites a human being, the parasite is released into its bloodstream. Once the parasites are inside the human body, they travel to the liver, where they mature. After several days, the mature parasites enter the bloodstream and begin to infect red blood corpuscles or RBCs Within 48-72 hours, the parasites inside the red blood cells multiply which causes the infected cells to burst open. The parasites continue to infect red blood cells, leading to symptoms that occur in cycles that last two to three days at a time. Malaria is generally found in tropical and subtropical climates where the parasites can survive and thrive. The World Health Organization (WHO) Trusted Source reports state that in 2016, there were an estimated 216 million cases of malaria across 91 countries.
Malaria is caused by the female anopheles mosquito which carries the plasmodium protozoa responsible for the disease. There are four types of malarial parasite which can infect humans:
P. falciparum causes a severe form of the disease and those who contract this form of malaria have a higher risk of death. An infected mother can also pass the disease to the foetus in the womb. This condition is known as congenital malaria.
In the uncomplicated forms, which last 6-10 hours and recur every second day the general malaria disease symptoms are:
Seizures can be observed in younger people with the disease
Sweats and then a return to normal temperature with fatigue
In the Severe Form of Malaria, the Symptoms are:
Deep breathing and respiratory distress
Abnormal bleeding and signs of anaemia
The malaria fever has the following characteristics; chills, fever, rigor followed by sweating, called as the cold stage, the hot stage and sweating stage respectively.
The first cold stage lasts 15-60 minutes and is characterised by a feeling of cold and shivering.
The cold stage is followed by the hot stage, with fever from 39-41.5°C, lasting 2-6 hours, also associated with flushed and dry skin, headaches, nausea and vomiting.
At the end of the cold stage, the fever drops rapidly and the patient sweats profusely over a period of 2-4 hours.
The mode of infection in malaria occurs through the following cycle:
A female anopheles mosquito becomes infected by feeding on a person who has malaria.
The mosquito becomes the carrier of the parasite and it then transmits into a human body when the carrier mosquito bites a human
The parasite enters the body and travels to the liver where it matures. (it can lie dormant upto a year)
When the parasites mature they leave the liver and infect the RBCs of the bloodstream. (the symptoms start showing at this stage)
The cycle continues when an uninfected mosquito bites an infected person.
Usage of shared syringes or needles
The complete development of the malarial parasite takes place in two different hosts; humans and mosquitoes. The malarial parasite, plasmodium, exists in the form of a motile sporozoite. The female Anopheles mosquito which is the vector of malaria, transmits the sporozoites into the hosts. It is inside the mosquito’s body that the actual development and maturing of the plasmodium parasite takes place. The parasitic cells that are produced in the human body reach the intestine of the mosquito. Here, the male and females cells of the parasite fertilise each other to lead to the formation of a sporozoite. After maturing, the sporozoite breaks out of the mosquito’s intestine and migrates to the salivary glands. When an infected mosquito bites a human, the sporozoites are transmitted into the bloodstream through the mosquito’s saliva. Then they travel via the blood and accumulate in the liver. These parasites multiply within the liver and mature by damaging the liver and rupturing the blood cells in the body The parasites reproduce asexually in the RBCs, causing lysis of the cells and releasing more parasites to infect more cells. The rupture of red blood cells by the malaria parasite releases a toxin called haemozoin which causes the infected to experience a condition known as the chills and eventually one of the causes of malaria fever. [Image to be Added Soon]
Vector Control: Vector control is the effective way of preventing and reducing malaria transmission. There are two forms of vector control:
Insecticide Treated Mosquito Nets: Sleeping under/inside an insecticide-treated net can reduce contact with mosquitos. It acts as a physical barrier and the insecticide also keeps other harmful insects away.
Indoor Spraying With Residual Insecticides: This method can rapidly reduce malaria transmission. A particular insecticide is sprayed within a housing structure once or twice a year. This results in significant increase in protection from the disease for the community.
Antimalarial Drugs: Antimalarial drugs can also be used to prevent malaria. For travellers, the disease can be prevented through chemoprophylaxis, which acts by suppressing the blood stage of malaria infections, thereby preventing malaria disease.
For women who are pregnant and are living in moderate-to-high transmission areas, WHO recommends intermittent preventive treatment with sulfadoxine-pyrimethamine, at each scheduled antenatal visit after the first trimester. For infants who live in high-transmission areas of Africa, 3 doses of intermittent preventive treatment with sulfadoxine-pyrimethamine are recommended, delivered alongside routine vaccinations.
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