Diagnosis and preventation of malaria

Further information: Romanowsky stain, Malaria Rapid Diagnostic Tests
Blood smear from a P. falciparum culture (K1 strain). Several red blood cells have ring stages inside them. Close to the center there is a schizont and on the left a trophozoite.

Since Charles Laveran first visualised the malaria parasite in blood in 1880,[38] the mainstay of malaria diagnosis has been the microscopic examination of blood.

Fever and septic shock are commonly misdiagnosed as severe malaria in Africa, leading to a failure to treat other life-threatening illnesses. In malaria-endemic areas, parasitemia does not ensure a diagnosis of severe malaria, because parasitemia can be incidental to other concurrent disease. Recent investigations suggest that malarial retinopathy is better (collective sensitivity of 95% and specificity of 90%) than any other clinical or laboratory feature in distinguishing malarial from non-malarial coma.

Although blood is the sample most frequently used to make a diagnosis, both saliva and urine have been investigated as alternative, less invasive specimens.

Symptomatic diagnosis

Areas that cannot afford even simple laboratory diagnostic tests often use only a history of subjective fever as the indication to treat for malaria. Using Giemsa-stained blood smears from children in Malawi, one study showed that when clinical predictors (rectal temperature, nailbed pallor, and splenomegaly) were used as treatment indications, rather than using only a history of subjective fevers, a correct diagnosis increased from 21% to 41% of cases, and unnecessary treatment for malaria was significantly decreased.
Microscopic examination of blood films
For more details on individual parasites, see P. falciparum, P. vivax, P. ovale, P. malariae.

The most economic, preferred, and reliable diagnosis of malaria is microscopic examination of blood films because each of the four major parasite species has distinguishing characteristics. Two sorts of blood film are traditionally used. Thin films are similar to usual blood films and allow species identification because the parasite's appearance is best preserved in this preparation. Thick films allow the microscopist to screen a larger volume of blood and are about eleven times more sensitive than the thin film, so picking up low levels of infection is easier on the thick film, but the appearance of the parasite is much more distorted and therefore distinguishing between the different species can be much more difficult. With the pros and cons of both thick and thin smears taken into consideration, it is imperative to utilize both smears while attempting to make a definitive diagnosis.

From the thick film, an experienced microscopist can detect parasite levels (or parasitemia) down to as low as 0.0000001% of red blood cells. Diagnosis of species can be difficult because the early trophozoites ("ring form") of all four species look identical and it is never possible to diagnose species on the basis of a single ring form; species identification is always based on several trophozoites.
Field tests

In areas where microscopy is not available, or where laboratory staff are not experienced at malaria diagnosis, there are antigen detection tests that require only a drop of blood. Immunochromatographic tests (also called: Malaria Rapid Diagnostic Tests, Antigen-Capture Assay or "Dipsticks") have been developed, distributed and fieldtested. These tests use finger-stick or venous blood, the completed test takes a total of 15–20 minutes, and a laboratory is not needed. The threshold of detection by these rapid diagnostic tests is in the range of 100 parasites/µl of blood compared to 5 by thick film microscopy. The first rapid diagnostic tests were using P. falciparum glutamate dehydrogenase as antigen.[43] PGluDH was soon replaced by P.falciparum lactate dehydrogenase, a 33 kDa oxidoreductase [EC 1.1.1.27]. It is the last enzyme of the glycolytic pathway, essential for ATP generation and one of the most abundant enzymes expressed by P.falciparum. PLDH does not persist in the blood but clears about the same time as the parasites following successful treatment. The lack of antigen persistence after treatment makes the pLDH test useful in predicting treatment failure. In this respect, pLDH is similar to pGluDH. The OptiMAL-IT assay can distinguish between P. falciparum and P. vivax because of antigenic differences between their pLDH isoenzymes. OptiMAL-IT will reliably detect P. falciparum down to 0.01% parasitemia and other species down to 0.1%. Paracheck-Pf will detect parasitemias down to 0.002% but will not distinguish between falciparum and non-falciparum malaria. Parasite nucleic acids are detected using polymerase chain reaction. This technique is more accurate than microscopy. However, it is expensive, and requires a specialized laboratory. Moreover, levels of parasitemia are not necessarily correlative with the progression of disease, particularly when the parasite is able to adhere to blood vessel walls. Therefore more sensitive, low-tech diagnosis tools need to be developed in order to detect low levels of parasitemia in the field.
Molecular methods

Molecular methods are available in some clinical laboratories and rapid real-time assays (for example, QT-NASBA based on the polymerase chain reaction)[44] are being developed with the hope of being able to deploy them in endemic areas.
Rapid antigen tests
Further information: Malaria Rapid Diagnostic Tests

According to a manufacturer, a commercially available test will reliably detect falciparum down to 0.01% parasitemia and non-falciparum down to 0.1%, and another can detect parasitemias down to 0.002% but will not distinguish between falciparum and non-falciparum malaria. Parasite nucleic acids are detected using polymerase chain reaction. This technique is more accurate than microscopy. However, it is expensive, and requires a specialized laboratory. Moreover, levels of parasitemia are not necessarily correlative with the progression of disease, particularly when the parasite is able to adhere to blood vessel walls. Therefore more sensitive, low-tech diagnosis tools need to be developed in order to detect low levels of parasitaemia in the field.

Prevention
Anopheles albimanus mosquito feeding on a human arm. This mosquito is a vector of malaria and mosquito control is a very effective way of reducing the incidence of malaria.

Methods used to prevent the spread of disease, or to protect individuals in areas where malaria is endemic, include prophylactic drugs, mosquito eradication, and the prevention of mosquito bites. The continued existence of malaria in an area requires a combination of high human population density, high mosquito population density, and high rates of transmission from humans to mosquitoes and from mosquitoes to humans. If any of these is lowered sufficiently, the parasite will sooner or later disappear from that area, as happened in North America, Europe and much of Middle East. However, unless the parasite is eliminated from the whole world, it could become re-established if conditions revert to a combination that favors the parasite's reproduction. Many countries are seeing an increasing number of imported malaria cases due to extensive travel and migration.

Many researchers argue that prevention of malaria may be more cost-effective than treatment of the disease in the long run, but the capital costs required are out of reach of many of the world's poorest people. Economic adviser Jeffrey Sachs estimates that malaria can be controlled for US$3 billion in aid per year.

The distribution of funding varies among countries. Countries with large populations do not receive the same amount of support. The 34 countries that received a per capita annual support of less than $1 included some of the poorest countries in Africa.

Brazil, Eritrea, India, and Vietnam have, unlike many other developing nations, successfully reduced the malaria burden. Common success factors included conducive country conditions, a targeted technical approach using a package of effective tools, data-driven decision-making, active leadership at all levels of government, involvement of communities, decentralized implementation and control of finances, skilled technical and managerial capacity at national and sub-national levels, hands-on technical and programmatic support from partner agencies, and sufficient and flexible financing.

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SIMPLE SELF-PROTECTION MEASURES FROM MALARIA

Personal protective measures can greatly reduce the risk of being bitten by the anopheles mosquito. Because of its night time feeding habits, malaria transmission occurs primarily between dawn & dusk.

1. Correct use of mosquito nets (if accommodation not air conditioned). For added protection for up to 3 months or longer, mosquito nets can be soaked in 1 % solution of PERMETHRIN (or other repellent/insecticide). If resident in a malarious area, curtains can be treated in a similar manner.
2. Use of mosquito coils (obat anti nyamuk) and "knockdown spray" (containing pyrethoids) - spray insecticide in cool dark places where mosquitoes lurk.
3. Avoid use of dark colored clothing, perfumes and colognes in the evening and at night all these attract mosquitoes.
4. Use an effective mosquito repellent on exposed skin and clothing. DEET (diethylmethylbenzamide) is an effective safe component of good repellents. The actual concentration of DEET varies widely between different manufacturers, and can be as high as 90% (too high for safety). Choose a repellent with between 30-45% DEET (unless pregnant in which case concentration should be < 35%) and take the following precautions:

• apply sparingly and only to exposed skin
• never apply high concentrations to skin (use those for clothing)
• do not inhale or swallow or get it in eyes or mucous membranes
• do not apply to hands that may touch eyes or mouth
• do not apply to wounds, rashes, or abrasions
• wash repellent off after coming indoors to stay
• if skin starts to burn, wash repellent off and seek medical advice

DEET-based repellents should last for up to 4 hours.
Although mosquitoes can bite through cloth it is still better to cover up.

5.  Destroy mosquitoes and their larvae (young). Mosquitoes breed in standing water. Clear the neighborhood of ponds & pits. Cover all water containers and any objects that can trap rain water.

ANTI-MALARIA CHEMOPROPHYLAXIS
There are many drugs used for malaria prophylaxis and medical opinion differs internationally as to the best medications to use.

As well as this difference of opinion, the situation is further complicated by the increasing emergence and spread of resistance to some anti-malaria prophylactics, especially with respect to P. falciparum and P. vivax. You should be aware of the recommendations current in your home country, and that advice can be 'fine-tuned' by the experience of doctors locally. AEA's recommendations are based on up-to-date personal experience, clinical experience with patients, and reference to the most recent publications by specialist advisory bodies in South East Asia, the UK and Australia.

Resistance to anti-malaria prophylaxis comes in 3 grades:

1. No resistance; in this case chloroquine alone is adequate for prophylaxis.
2. Chloroquine resistance; this occurs in many places in the world. Indonesia has many areas of known chloroquine resistance, particularly (South East) Kalimantan, East Maluku, Lombok, and Flores, so if chloroquine is used it should be supplemented (with Proguanil).
3. Antifolate resistance; this is emerging in South East Asia, and in Irian Jaya and other islands of East Indonesia. In this type of resistance, the parasite is resistant to chloroquine and Fansidar.

GENERAL RULES FOR ANTI-MALARIA PROPHYLAXIS

1. 1. Fansidar as a prophylactic is no longer recommended due to side-effects, although it is still recommended for standby treatment.
2. The use of mefloquine (Larium) is hotly debated but as usual when there is more heat than light, the debated tends to be polarized rather than illuminating. The author believes this drug is very useful especially for short-term prophylaxis and definitely as "stand-by" treatment; for longer-term use this drug is best chosen only after discussion with your medical advisor.
3. Always check for allergy to medication. If a patient is allergic to 'sulfa' drugs, then they should not take Fansidar. Some patients especially those of Asian or Mediterranean origin should be tested for G6PD deficiency.
4. 4. Prophylaxis should be commenced 1-2 weeks before traveling, to establish effective blood levels, to establish a routine of regular taking if medication, and to make sure that any early side effects occur near to medical help and not in a remote area (start mefloquine 3 weeks before). The medication should be continued for 4 weeks after returning from malarious areas, with the exception of doxycycline.
5. Doxycycline (Vibramycin) is a reasonable daily alternative for short stays of up to 6 weeks and can be supplemented with weekly chloroquine. It should not be taken by children whose permanent teeth are not complete, nor by pregnant women.
6. Some authorities recommend that people traveling through or working in a malarious area, start taking supplements of Vitamin B two weeks beforehand. There is some evidence that metabolites of Vitamin B cause an odor that discourages Anopheles mosquitoes.
7.  Always have enough medicine to last for the trip / stay as the particular recommended medication may not be available in remote areas.

RECOMMENDATIONS FOR PROPHYLAXIS
(ALWAYS check side-effects and contra-indications before taking and DO NOT SELF-PRESCRIBE)

For healthy adults:

1. Doxycyline (Vibramycin) is an alternative for short stays of about 2-6 weeks; 100 mg once a day with food, starting 2 days before and finishing 2 weeks after exiting malarious area. or
2. Mefloquine (Larium) 250 mg (1 tablet) once a week, before, during, and for 4 weeks after exposure. Do not use Fansimef (Fansidar plus Mefloquine) for prophylaxis. Do not use if any history of convulsions, depressive illness, cardiac conditions. ALWAYS check its use with a doctor before taking.or
3. Chloroquine and Proguanil for longer stays;

Chloroquine 2x 150 mg tablets once a week, same time each week
Proguanil 2x 100 mg tablet once a day, same time each day
both starting 2 weeks before and finishing 4 weeks after exiting.
For pregnant women:
 

Malaria can cause intrauterine fetal death, miscarriage, congenital infection, premature labor and pre-eclamptic toxemia.

We strongly advise women who are pregnant or trying to become pregnant not to go to a malarious area (anywhere outside metropolitan Jakarta, Bandung, Yogya, Surabaya and Bali).

Doxycycline is contraindicated in pregnancy; Proguanil is considered safe; Chloroquine is considered safe but alone constitutes insufficient protection. Mefloquine is not known to be safe in the 1st trimester but has been used in the 2nd and 3rd trimesters without known problems so far.

For children:

In this group the emphasis is on bite prevention. Antimalarials for children must be prescribed by a pediatrician and doses individualized:

Chloroquine phosphate / chloroquine sulfate: 50 mg chloroquine base per tablet: DOSE: 5.0 mg / kg / week up to maximum adult dose

Chloroquine sulfate syrup (Nivaquine syrup): 25 mg chloroquine base per 5 ml syrup; DOSE: 1.0 ml / kg / week (measure accurately using a syringe)

Proguanil syrup: DOSE 3 mg / kg / day

REMEMBER THAT NO DRUG IS AS EFFECTIVE AS PREVENTING BITES IN THE FIRST PLACE

IF SICK WITH A FEVER AFTER VISITING A MALARIOUS AREA ALWAYS GIVE THE DOCTOR A TRAVEL HISTORY AND IF NECESSARY ASK HIM / HER "COULD THIS BE MALARIA"? ESPECIALLY IF 'BACK HOME'

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Main symptoms of malaria

Symptoms of malaria include fever, shivering, arthralgia (joint pain), vomiting, anemia (caused by hemolysis), hemoglobinuria, retinal damage,[10] and convulsions. The classic symptom of malaria is cyclical occurrence of sudden coldness followed by rigor and then fever and sweating lasting four to six hours, occurring every two days in P. vivax and P. ovale infections, while every three for P. malariae. P. falciparum can have recurrent fever every 36–48 hours or a less pronounced and almost continuous fever. For reasons that are poorly understood, but that may be related to high intracranial pressure, children with malaria frequently exhibit abnormal posturing, a sign indicating severe brain damage.

Malaria has been found to cause cognitive impairments, especially in children. It causes widespread anemia during a period of rapid brain development and also direct brain damage. This neurologic damage results from cerebral malaria to which children are more vulnerable. Cerebral malaria is associated with retinal whitening, which may be a useful clinical sign in distinguishing malaria from other causes of fever.

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Diagnosis and treatment for malaria

Early diagnosis of malaria and its effective and timely treatment reduces morbidity and prevents death from malaria. Diagnostic tools - microscopy and rapid diagnostic tests - and medicines - artemisinin-based combination treatments - allow effective case management. Diagnostic tests and combination medicines of good quality need to be used correctly and strategically to reduce malaria morbidity and mortality and to reduce the risk of parasite resistance to medicines.

Prompt and accurate diagnosis of malaria is part of effective disease management

Diagnosis
Prompt and accurate parasitological confirmation of malaria is essential for effective disease management and malaria surveillance. The patient should be treated early with a safe and effective antimalarial medicine

Treatment
The patient should be treated early with a safe and effective antimalarial medicine.

Antimalarial drug resistance hinders malaria control and is therefore a major public health problem
Drug resistance
Antimalarial drug resistance hinders malaria control and is therefore a major public health problem.

Is important…
Quality of antimalarial medicines
Observing stringent quality standards for antimalarial medicine ensures safe and effective medicines are consistently made available for widespread use.

The HMM strategy aims to improve commonly ineffective self-medication practices
Home management of malaria (HMM)
The HMM strategy aims to ensure access to prompt malaria diagnosis and effective treatment near the home.

Finance and procurement
Pricing and affordability of artemisinin-based are key elements to increase access to quality, safe and effective antimalarial medicines.

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Vector control of malaria

Vector control remains the most generally effective measure to prevent malaria transmission and therefore is one of the four basic technical elements of the Global Malaria Control Strategy.

The principal objective of vector control is the reduction of malaria morbidity and mortality by reducing the levels of transmission. Vector control methods vary considerably in their applicability, cost and sustainability of their results.
Methods

A decision-making process for the management of vector populations
Integrated vector managemententering houses or sleeping units

Indoor residual spraying
Reduces transmission by reducing the survival of malaria vectors entering houses or sleeping units.

Antimalarial drug resistance hinders malaria control and is therefore a major public health problem
Insecticide-treated materials
Insecticide treated nets, if used by the total population, have shown to be able to lower transmission by 90%, malaria incidence by 50% and all case child mortality by 18 %.

Facilitating access to artemisinin-based combination antimalarial drug products of acceptable quality through the assessment of compliance with WHO recommended standards

Other methods
In some cases environmental management and/or larviciding can be recommended as effective malaria control tools.
The choice of vector control

The choice of vector control will depend on:

    the magnitude of the malaria burden;
    the feasibility of timely and correct application of the required interventions;
    the possibility of sustaining the resulting modified epidemiological situation.

WHO recommends a systematic approach to vector control-based on evidence and knowledge of the local situation. This approach is called Integrated vector management (IVM).

Please refer to report Malaria vector control and personal protection for a review of the current vector control strategies and their effectiveness in various operational and eco-epidemiological settings and identified challenges for implementation in different health systems.

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