Plasmodium: Difference between revisions
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Plasmodium
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*Mostly caused by ''P. falciparum'', though can also be caused by ''P. vivax'' |
*Mostly caused by ''P. falciparum'', though can also be caused by ''P. vivax'' |
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====Criteria (CATMAT and WHO)==== |
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*Severe disease is defined as the presence of any one of criteria below |
*Severe disease is defined as the presence of any one of criteria below |
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*Clinical |
*Clinical |
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**Prostration (unable to walk to sit up without assistance) or impaired consciousness |
**Prostration (unable to walk to sit up without assistance) or impaired consciousness (GCS less than 11 in adults) |
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**Pulmonary edema (radiologically confirmed, or oxygen saturation <92% with respiratory rate >30/min) |
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**Respiratory distress |
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**Multiple convulsions (>2 in 24 hours), which can be from cerebral malaria, hypoglycemia, severe metabolic acidosis, |
**Multiple convulsions (>2 in 24 hours), which can be from cerebral malaria, hypoglycemia, severe metabolic acidosis, or other |
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**Circulatory collapse (SBP <80 in adults, <50 in children) |
**Circulatory collapse (SBP <80 in adults, <50 in children, or capillary refill ≥ 3 s) |
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**Abnormal significant bleeding (including prolonged bleeding from nose, gums, venepuncture sites) |
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**Pulmonary edema |
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⚫ | |||
**Abnormal bleeding |
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⚫ | |||
**Hemoglobinuria (macroscopic) |
**Hemoglobinuria (macroscopic) |
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*Laboratory |
*Laboratory |
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**Severe anemia (Hb ≤70 or Hct <20%) |
**Severe anemia (Hb ≤70 or Hct <20%) |
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**Hypoglycemia (<2.2) |
**Hypoglycemia (<2.2) |
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**Acidosis (pH <7.25 or bicarb <15) |
**Acidosis (pH <7.25 or bicarb <15 or base deficit >8) |
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**Renal impairment (creatinine >265) |
**Renal impairment (creatinine >265 or urea >20) |
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**Hyperlactatemia ( |
**Hyperlactatemia (≥5 mmol/L) |
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**Hyperparasitemia |
**Hyperparasitemia |
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***≥2% for children <5 years |
***≥2% for children <5 years |
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**Aldolase less sensitive for ''P. ovale'' and ''P. malariae'' and depends on parasitemia |
**Aldolase less sensitive for ''P. ovale'' and ''P. malariae'' and depends on parasitemia |
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**Both may cross-react with ANA and RF, and with [[dengue]], [[hepatitis C]], [[leishmaniasis]], [[trypanosomiasis]], [[schistosomiasis]], [[tuberculosis]], and [[toxoplasmosis]] |
**Both may cross-react with ANA and RF, and with [[dengue]], [[hepatitis C]], [[leishmaniasis]], [[trypanosomiasis]], [[schistosomiasis]], [[tuberculosis]], and [[toxoplasmosis]] |
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**Increasing pfhrp2/3 mutations leading to false negatives (higher in South America and Africa)[[CiteRef::jejaw zeleke2022pl]] |
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*BinaxNOW is the only test in Canada |
*BinaxNOW is the only test in Canada |
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**3 bands |
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**T1 band: histidine-rich protein-2 (HRP-2) of ''P. falciparum'', which is fairly specific and sensitive |
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***C band: control |
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⚫ | |||
** |
***T1 band: histidine-rich protein-2 (HRP-2) of ''P. falciparum'', which is fairly specific and sensitive |
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⚫ | |||
⚫ | |||
**Interpretation |
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⚫ | |||
**C+ / |
***C+ / T1+ / T2+: ''P. falciparum'' or mixed |
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⚫ | |||
⚫ | |||
***C+ / T1– / T2–: no malaria |
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*Can remain positive for up to 4 weeks due to detection of dead organisms, persistent gamecotyes, and slow antigen clearance, so are not used to document treatment success |
*Can remain positive for up to 4 weeks due to detection of dead organisms, persistent gamecotyes, and slow antigen clearance, so are not used to document treatment success |
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*Because of the low specificity, every patient with a positive RDT must have a peripheral blood film |
*Because of the low specificity, every patient with a positive RDT must have a peripheral blood film |
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===Molecular Testing=== |
===Molecular Testing=== |
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*PCR |
*PCR and LAMP are available |
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* |
*PCR is done reflexively in Ontario to confirm species and detect a mixed infection |
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*LAMP may need to replace RDT due to increasing falciparum false-negatives |
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==Management== |
==Management== |
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==Further Reading== |
==Further Reading== |
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*Boggild A, ''et al''. [https://www.canada.ca/en/public-health/services/ |
*Boggild A, ''et al''. [https://www.canada.ca/en/public-health/services/catmat/canadian-recommendations-prevention-treatment-malaria.html Canadian recommendations for the prevention and treatment of malaria: Statements from the Committee to Advise on Tropical Medicine and Travel (CATMAT)]. |
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**A continuously-updated version is maintained [https://www.canada.ca/en/public-health/services/catmat/canadian-recommendations-prevention-treatment-malaria.html online]. |
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*[https://www.cdc.gov/malaria/diagnosis_treatment/clinicians1.html CDC Treatment of Malaria: Guidelines For Clinicians (United States)] |
*[https://www.cdc.gov/malaria/diagnosis_treatment/clinicians1.html CDC Treatment of Malaria: Guidelines For Clinicians (United States)] |
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*[https://www.who.int/teams/global-malaria-programme/guidelines-for-malaria WHO Guidelines for Malaria] |
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{{DISPLAYTITLE:''Plasmodium'' |
{{DISPLAYTITLE:''Plasmodium''}} |
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[[Category:Haemosporida]] |
[[Category:Haemosporida]] |
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[[Category:Travel medicine]] |
[[Category:Travel medicine]] |
Latest revision as of 17:17, 27 September 2024
- Mosquito-borne protozoon that causes malaria
Background
Microbiology
- Intracellular protozoal parasite of red blood cells
- Species that cause human disease are: P. falciparum, P. vivax, P. ovale, P. malariae, and P. knowlesi (from the macaque monkey)
- Most common cause of disease in humans is Plasmodium falciparum
- P. knowlesi looks like P. malariae microscopically, but has a higher (>1%) parasitemia with a clinical course more like P. falciparum
- Identified on thick-and-thin Giemsa-stained blood films
Life Cycle
- Infected mosquito injects sporozoites into human
- Sporozoites infect the hepatocytes, which develop intracellular schizonts
- P. vivax and P. ovale can have prolonged (months to years) liver stages during which the patient is asymptomatic
- The hepatocytes rupture and release trophozoites, which infect erythrocytes and mature into trophozoites
- Trophozoites develop into schizonts, then rupture the erythrocyte to release more merozoites
- These cycles of merozoite to trophoziote to schizont to merozoite explain the periodic fevers
- Trophozoites can also develop into gametocytes (micro- or macro-gametocytes), which are taken up by the mosquito
- In the mosquito, the micro- and macro-gametocytes join to form a zygote, which matures into an ookinete then oocyst, which releases infective sporozoites
Pathophysiology
- Infected red blood cells adhere to endothelial cells, and clump, causing rosetting
- This causes microvascular obstruction and ischemia, which causes cerebral malaria and metabolic acidosis
- Can cause marrow suppression
- P. falciparum manages to avoid splenic sequestration
- Hypoglycemia
- In children, hypermetabolic and consumes glucose
- In adults, hyperinsulin state and quinine also contributes
Epidemiology
- Transmitted by female Anopheles mosquitoes, but can also be transmitted through blood transfusions
- Distribution is that of the Anopheles mosquito: tropical and subtropical regions worldwide with the exception of North America, Europe, and Australia
- Distribution varies by species
- P. falciparum in tropical and subtropical Americas, Africa, and Southeast Asia
- P. vivax in the Americas, India, and Southeast Asia
- P. malariae in tropical and subtropical Americas, Africa, and Southeast Asia
- P. ovale in sub-Saharan Africa
- P. knowlesi in Southeast Asia
- Resistance varies geographically
- Chloroquine
- Chloroquine-resistant P. falciparum is widespread in sub-Saharan Africa, Asia, and the Americas
- Chloroquine-susceptible is in Mexico, regions west/north of the Panama Canal, Haiti, and the Dominican Republic, and parts of Middle East
- Chloroquine-resistant P. vivax is in Papua New Guinea and Indonesia, with case reports in many other countries
- Chloroquine-resistant P. malariae is found in Sumatra and Indonesia
- Chloroquine-resistant P. falciparum is widespread in sub-Saharan Africa, Asia, and the Americas
- Amodiaquine-resistant P. falciparum can be found in Africa and Asia
- Mefloquine-resistant P. falciparum is in Thailand, Cambodia, Myanmar, and Vietnam, with case reports in Brazil and Africa
- Sulfadoxine-pyrimethamine resistance is widespread in Southeast Asia, the Amazon Basin, and Africa
- Atovaquone-proguanil resistance is increasing but still rare
- Reduced quinine susceptibility is reported in Southeast Asia, sub-Saharan Africa, and South America
- Reduced artemisinin susceptibility is reported in Cambodia, Thailand, Vietnam, and Myanmar
- Doxycycline has no known resistance
- Chloroquine
Clinical Manifestations
- History of travel to an endemic country
- Non-specific febrile illness with headache, myalgias, and malaise
- Incubation period can vary, but is generally 9 to 14 days for P. falciparum, 12 to 18 days P. vivax and P. ovale, and longer for others
- Fevers are often periodic, appearing based on rupture of schizonts (tertian and quartan fever)
- q24h: P. falciparum, but wide variation
- q48h: P. vivax or P. ovale
- q72h: P. malariae
- May vary by timepoint in infection, with early infection having daily or more frequent fevers from shedding from the liver stage
- Leukopenia more common
- May have concurrent bacterial or other infections
Severe Malaria
- Mostly caused by P. falciparum, though can also be caused by P. vivax
Criteria (CATMAT and WHO)
- Severe disease is defined as the presence of any one of criteria below
- Clinical
- Prostration (unable to walk to sit up without assistance) or impaired consciousness (GCS less than 11 in adults)
- Pulmonary edema (radiologically confirmed, or oxygen saturation <92% with respiratory rate >30/min)
- Multiple convulsions (>2 in 24 hours), which can be from cerebral malaria, hypoglycemia, severe metabolic acidosis, or other
- Circulatory collapse (SBP <80 in adults, <50 in children, or capillary refill ≥ 3 s)
- Abnormal significant bleeding (including prolonged bleeding from nose, gums, venepuncture sites)
- Jaundice (clinical, or total bilirubin >50)
- Hemoglobinuria (macroscopic)
- Laboratory
- Severe anemia (Hb ≤70 or Hct <20%)
- Hypoglycemia (<2.2)
- Acidosis (pH <7.25 or bicarb <15 or base deficit >8)
- Renal impairment (creatinine >265 or urea >20)
- Hyperlactatemia (≥5 mmol/L)
- Hyperparasitemia
- ≥2% for children <5 years
- ≥5% for non-immune adults and children ≥5 years
- ≥10% for semi-immune adults and children ≥5 years
- Non-immune: born in non-endemic or low-transmission areas (e.g. as travellers), and those who are more than 6 to 12 months away from malaria exposure
- Semi-immune: birth and long-term residence in an endemic country and prior episodes of malaria
Cerebral Malaria
- Classically defined as coma not attributable to other cause such as post-ictal state, hypoglycemia, or another disease altogether1
- Seizures are common
- Most suggestive physical examination finding that helps to rule in malaria and rule out other causes of fever and coma is malarial retinopathy, which can include:
- Patchy retinal whitening in the macula (especially peri-foveal) and/or in the peripheral retina
- White or orange discolouration of retinal vessels
- White-centred haemorrhages
- Papilloedema
- Pathophysiology is the sequestration of erythrocytes in the cerebral microvessels
Blackwater Fever
- Caused by massive hemolysis leading to hemoglobinuria, usually in the context of severe malaria but with low or undetectable parasitemia
- Syndrome of loin pain, abdominal pain, restlessness, vomiting, diarrhea, and polyuria that is followed by oliguria and passage of dark red or black urine
- May have hepatosplenomegaly, profound anemia, and jaundice
- Unclear if it is triggered by exposure to quinine
Malaria in Pregnancy
- Accumulation of infected erythrocytes in the placenta, causing IUGR, prematurity, and neonatal mortality
- P. falciparum has a tropism for the placenta, and can form a reservoir for recurrence even after appropriate treatment
Late or Relapsing Malaria
- P. vivax and P. ovale can have liver stages (hypnozoites) that lie latent for months to years before causing relapses
- P. malariae can have a low-level asymptomatic parasitemia lasting for years before presentation
Differential Diagnosis
- Essentially any cause of undifferentiated fever
- See also fever in the returned traveller
Diagnosis
Thick and Thin Peripheral Blood Films
- Thick for detecting parasites, thin for parasitemia and species
- Usually done three times over three days for improved sensitivity
- Clues on microscopy:
- Banana or crescent-shaped gametocytes: P. falciparum
- Only ring forms, without trophozoites: P. falciparum more likely
- Amoeboid trophozoite: P. vivax
- Ring form in an enlarged erythrocyte: P. vivax
- Band-shaped trophozoite: P. malariae
- Ring form in an oval-shaped erythrocytes: P. ovale
- Looks like P. malariae but clinically severe: P. knowlesi
Rapid Diagnostic Antigen Test (RDT)
- Detects Plasmodium antigen in circulating blood
- Good sensitivity and specificity for falciparum malaria, but lower sensitivity (66-88%) for non-falciparum or at low levels of parasitemia
- Aldolase less sensitive for P. ovale and P. malariae and depends on parasitemia
- Both may cross-react with ANA and RF, and with dengue, hepatitis C, leishmaniasis, trypanosomiasis, schistosomiasis, tuberculosis, and toxoplasmosis
- Increasing pfhrp2/3 mutations leading to false negatives (higher in South America and Africa)2
- BinaxNOW is the only test in Canada
- 3 bands
- C band: control
- T1 band: histidine-rich protein-2 (HRP-2) of P. falciparum, which is fairly specific and sensitive
- T2 band: aldolase, a common antigen of four species of human malaria parasites
- Interpretation
- C+ / T1+ / T2+: P. falciparum or mixed
- C+ / T1+ / T2–: P. falciparum
- C+ / T1– / T2+: non-falciparum
- C+ / T1– / T2–: no malaria
- 3 bands
- Can remain positive for up to 4 weeks due to detection of dead organisms, persistent gamecotyes, and slow antigen clearance, so are not used to document treatment success
- Because of the low specificity, every patient with a positive RDT must have a peripheral blood film
Molecular Testing
- PCR and LAMP are available
- PCR is done reflexively in Ontario to confirm species and detect a mixed infection
- LAMP may need to replace RDT due to increasing falciparum false-negatives
Management
- All returned travellers with fever should have thick and thin smears to rule out malaria
- Management depends on species and susceptibility (predicted by country of acquisition), and severity (including the level of parasitemia)
- Most of the world has chloroquine-resistant P. falciparum, so when in doubt, treat all P. falciparum malaria as resistant
- All patients with P. falciparum malaria should be considered for hospital admission
- If severe, advocate for ICU-level care
- If severe, monitor for hypoglycemia
- Monitor with daily peripheral blood films until they are negative
Concurrent Supportive Care
- Fluid resuscitation as needed (too much may be harmful in children)
- Rule out hypoglycemia if sudden change in clinical status (worsened with quinine)
- Avoid steroids, which are associated with worse outcomes in cerebral malaria
- Correct coagulopathy and bleeding with blood products and vitamin K
- If shock develops, treat empirically with antibiotics while getting blood cultures to rule out intercurrent bacteremia
Uncomplicated Malaria
- Chloroquine-sensitive P. falciparum (Mexico, Central America west of the Panama Canal, Haiti, the Dominican Republic, and most of the Middle East), P. vivax, P. ovale, P. malariae, and P. knowlesi
- Oral chloroquine 600 mg base PO once, followed by 300 mg base PO at 6, 24, and 48 hours
- The dose for salt is 1000 mg and 500 mg
- If from Papua New Guinea or Indonesia adjacent to Papua New Guinea, treat with atovaquone-proguanil
- Oral chloroquine 600 mg base PO once, followed by 300 mg base PO at 6, 24, and 48 hours
- Chloroquine-resistant P. falciparum (most of the world) or chloroquine-resistant P. vivax (Papua New Guinea and Indonesia)
- Atovaquone-proguanil 1000 mg/400 mg (4 tablets) PO daily for 3 days
- Alternative: quinine 542 mg base (650 mg salt) PO q8h for 3 to 7 days, plus doxycycline 100 mg PO bid for 7 days
- Prevention of relapsing P. vivax and P. ovale with radical cure
- Indicated for patients with prolonged exposure
- Primaquine 30 mg base daily for 14 days started concurrent with chloroquine
- First rule out G6PD deficiency and pregnancy
- If pregnant, just treat intermittently until after delivery with once-weekly chloroquine
Severe Malaria
- Usually due to P. falciparum, though can also be caused by P. vivax or P. knowlesi
- Admit to hospital, ideally ICU
- Frequent vitals and urine output
- Capillary glucose at least q4h
- Follow peripheral blood films q12-24h until cleared, and longer if pregnant
- With P. falciparum, can have some fluctuations due to irregular releasing from sequestration
- Parasitemia and clinical status should both improve by 48 to 72 hours
- Antimalarials
- Artesunate 2.4 mg/kg IV bolus over 1-2 minutes at 0, 12, 24, and 48 hours
- Artesunate is held in specific centres in Canada
- Should be followed by weekly CBC x4 to monitor for post-artesunate delayed hemolysis
- Four hours after the last dose, add one of the following:
- Atovaquone-proguanil 1000 mg/400 mg PO daily for 3 days
- Doxycycline 100 mg PO bid for 7 days
- Clindamycin 10 mg/kg IV followed by 5 mg/kg IV q8h for 7 days
- Quinine 5.8 mg/kg IV loading dose over 30 min followed by 8.3 mg/kg IV infused over 4 hours q8h for 7 days
- Dose of quinine dihydrochloride would be 7 mg/kg and 10 mg/kg
- Do not use loading dose if they had quinine within 24 hours or mefloquine within 2 weeks
- Switch to oral tablets as soon as able to swallow
- If no infusion pump, run the loading dose as quinine 16.7 mg/kg IV over 4 hours
- Monitor for cardiovascular toxicity (hypotension and QTc prolongation), ototoxicity (tinnitus and hearing loss), and hypoglycemia (which is exacerbated by quinine)
- Concurrent to last dose of quinine
- Atovaquone-proguanil 1000 mg/400 mg PO daily for 3 days
- Doxycycline 100 mg PO BID for 7 days
- Clindamycin 10mg/kg IV load followed by 5 mg/kg q8h for 7 days
- Clindamycin is the preferred treatment in pregnant women and children under 8 years
- Artesunate 2.4 mg/kg IV bolus over 1-2 minutes at 0, 12, 24, and 48 hours
- Treat seizures with benzodiazepines; no role for seizure prophylaxis
- Avoid steroids in cerebral malaria (worse outcomes)
- Exchange transfusion has been investigated; it reduces parasitemia but has no clinically-important benefits
- CATMAT still recommends considering it if parasitemia ≥10%
- Usually 5 to 10 units of pRBC
Pregnancy
- Uncomplicated chloroquine-susceptible malaria:
- Chloroquine, or artemether-lumefantrine after the first trimester
- Rather than terminal prophylaxis, treat with once weekly chloroquine until delivery, then reassess for terminal prophylaxis at that point
- Uncomplicated chloroquine-resistant P. falciparum or P. vivax:
- Mefloquine, quinine, and clindamycin, or artemether-lumefantrine after the first trimester
- Prevention of relapsing P. vivax and P. ovale:
- Maintained chloroquine prophylaxis 300 mg base (500 mg salt) PO weekly for the duration of their pregnancy
- Reassess for terminal with primaquine or tafenoquine prophylaxis after delivery
- Primaquine preferred if breastfeeding
- Severe malaria:
- Preferred is artesunate followed by clindamycin
- Alternative is quinine followed by clindamycin
- There are few data on artesunate in first trimester, but it appears safe, and the overall risk-benefit assessment favours treatment
- Monitor peripheral blood films q12-24h until cleared, and then for a few more days, to confirm clearance and no relapse from parasites sequestered in the placenta
- Other antimalarials
- Atovaquone-proguanil is likely safe and can be used after the first trimester for any of the above regimens
- Doxycycline, primaquine, and tafenoquine should be avoided in pregnancy
Prevention
Behavioural Interventions
- Mosquito avoidance (Anopheles mosquitoes are evening biters)
- Long sleeves & pants
- Insecticide-treated clothing
- Bed nets, screens on doors & windows
Chemoprophylaxis
Further Reading
References
- ^ Severe Malaria. Tropical Medicine & International Health. 2014;19:7-131. doi:10.1111/tmi.12313_2.
- ^ Ayalew Jejaw Zeleke, Asrat Hailu, Abebe Genetu Bayih, Migbaru Kefale, Ashenafi Tazebew Amare, Yalewayker Tegegne, Mulugeta Aemero. Plasmodium falciparum histidine-rich protein 2 and 3 genes deletion in global settings (2010–2021): a systematic review and meta-analysis. Malaria Journal. 2022;21(1). doi:10.1186/s12936-022-04051-7.