Malaria (Plasmodium Species)

Rick M. Fairhurst *, Thomas E. Wellems

Keywords

antimalarial; artemisinin; chemoprophylaxis; chloroquine; fever; malaria; Plasmodium falciparum; Plasmodium vivax; travel medicine; tropical medicine

The Malaria Problem

Malaria remains an overwhelming problem in tropical developing countries, accounting for more than 200 million cases and more than 600,000 deaths each year.¹^,²^,³ Nearly 40% of the world’s population is at risk for acquiring malaria.⁴^–⁷ In sub-Saharan Africa, most severe cases and deaths occur in children younger than 5 years and in pregnant women.

The introduction of chloroquine and dichlorodiphenyltrichloroethane (DDT) at the end of World War II brought dramatic new power to malaria control efforts worldwide. With postwar economic recovery and a renewed spirit of international cooperation, optimism ran high that the widespread use of these new compounds would eliminate malaria, and in 1955, the World Health Organization (WHO) launched its campaign to eradicate the disease. This goal proved overly optimistic, and the centrally organized DDT spraying programs at the core of the campaign were discontinued in 1967. The campaign, nevertheless, brought regional successes that coincided with other factors to reduce malaria incidence in many areas of the world (e.g., in Asia) (Fig. 276-1A).⁸

FIGURE 276-1 Malaria death rates after the introduction of chloroquine and subsequent evolution of chloroquine-resistant Plasmodium falciparum. A, Malaria death rates in the 20th century. Dramatic reductions in mortality were achieved outside sub-Saharan Africa. In Africa, mortality rates declined after the introduction of chloroquine but rose again after the spread of chloroquine resistance across the sub-Saharan region. B, Rise in mortality among children in the village of Mlomp, Senegal. Increased death rates were observed after chloroquine resistance entered the village, chiefly among children younger than 5 years, the most susceptible age group in highly endemic areas. (A modified from Carter R, Mendis KN. Evolutionary and historical aspects of the burden of malaria. Clin Microbiol Rev. 2002;15:564-594. B modified from Trape JF, Pison G, Preziosi MP, et al. Impact of chloroquine resistance on malaria mortality. C R Acad Sci III. 1998;321:689-697.)

A stark exception to this general progress is sub-Saharan Africa, where malaria remains deeply entrenched. Even the most committed spraying and eradication programs in endemic areas of this region could not defeat malaria’s efficient transmission by the Anopheles gambiae mosquito.⁹ The wide availability and use of chloroquine did, however, boost the health of young African children who suffer most from Plasmodium falciparum, the species responsible for the deadliest forms of malaria. As chloroquine became increasingly available in the 1950s to 1970s, death rates from malaria in Africa began to drop, approaching half the level of the prechloroquine years.¹⁰

Unfortunately, the massive use of chloroquine (hundreds of tons sufficient for hundreds of millions of treatments annually) in the 1980s¹¹ selected for chloroquine-resistant P. falciparum strains in Southeast Asia that entered and spread across Africa. In the 1980s and 1990s, malaria resurged and death rates increased. The impact of chloroquine resistance was especially evident in young children, who do not have the partially protective antimalarial immunity that usually develops after repeated episodes of the illness (Fig. 276-1B).¹²^,¹³ In the absence of a fully effective vaccine, success against malaria in Africa will continue to depend on effective drugs, such as artemisinin-based combination therapies, that are reliable, affordable, and readily available. Of importance, increased international support and funding for prevention, control, and elimination have reinvigorated the efforts of malaria control programs in recent years, averting an estimated 274 million cases and 1.1 million more deaths between 2001 and 2010.²

Plasmodium and Its Life Cycle

Plasmodium parasites belong to the Apicomplexa group of protozoa, which includes other pathogens, such as Babesia, Toxoplasma, and Cryptosporidium species. Apicomplexa are distinguished morphologically by the presence of a specialized complex of apical organelles (i.e., micronemes, rhoptries, and dense granules) involved in host cell invasion (see Fig. 276-4A).¹⁴ Four Plasmodium species are classified as human malaria parasites: P. falciparum, P. vivax, P. ovale, and P. malariae. Some malaria parasites of other primates (e.g., P. knowlesi, P. cynomolgi, and P. simium) can also infect humans under natural conditions.¹⁵ Indeed, with the recently appreciated extent of human infections from P. knowlesi, a natural pathogen of macaque monkeys, this parasite has been proposed to be a “fifth human malaria parasite” responsible for significant morbidity and mortality in Malaysia.¹⁶^–²⁰

In 1880, Alphonse Laveran²¹ first observed malaria parasites in a human blood sample, witnessing the exflagellation of microgametes that usually emerge in the mosquito. It was eventually established that parasites in the bloodstream reproduce asexually in the haploid state (Fig. 276-2). During erythrocytic development, a small minority of parasites undergo a poorly understood switch to sexual-stage development. The resulting male and female gametocytes are the forms that are taken up by and infect anopheline mosquitoes, as proved by Ronald Ross and Battista Grassi²²^,²³ in the 1890s. Gametocytes emerge from erythrocytes in the mosquito midgut as male and female gametes that cross-fertilize to form diploid zygotes, which in turn differentiate into ookinetes that burrow through the midgut wall. Each ookinete develops into an oocyst containing up to 1000 sporozoites, which emerge and are then carried by the insect hemolymph to invade the salivary glands. These processes in the mosquito require an incubation period of about 1 to 2 weeks.

FIGURE 276-2 The Plasmodium life cycle and disease patterns of recrudescence and relapse. Anopheline mosquitoes transmit malaria by injecting sporozoites into the human host. The sporozoites then invade hepatocytes, in which they develop into schizonts. Each infected hepatocyte ruptures to liberate 10,000 to 30,000 merozoites that invade circulating erythrocytes. Growth and development of the parasites in red cells result in subsequent waves of merozoite invasion. This asexual blood cycle repeats every 24 (Plasmodium knowlesi), 48 (Plasmodium falciparum, Plasmodium vivax, Plasmodium ovale), or 72 (Plasmodium malariae) hours, leading to amplification of parasite density; paroxysms of chills, fevers, and sweats; and other manifestations of disease. Malaria symptoms are typically experienced 2 to 4 weeks after the mosquito bite. If the parasites are not cleared (e.g., patient receives partially effective therapy), recrudescence of parasitemia and malaria symptoms can occur. Eradicating parasites with an effective drug regimen cures malaria. Some P. vivax and P. ovale parasites can postpone their development in the liver, persisting as latent forms called hypnozoites. Hypnozoites are not eradicated by standard therapy (e.g., chloroquine) directed against blood stages. Resumption of hypnozoite development months to years after initial infection can lead to malaria relapse that requires an additional round of drug therapy to treat recurrent symptoms and eradicate blood-stage parasites. A course of primaquine can prevent relapses of malaria, but this treatment may not always be successful because of inadequate patient compliance, interindividual variations of drug metabolism, or variable parasite responses to low or high drug doses.

Female mosquitoes inject sporozoites into humans while probing the dermis in preparation for taking a blood meal. Shortt and Garnham ²⁴ demonstrated in 1948 that sporozoites must first invade and replicate in hepatocytes before they can differentiate into merozoites capable of entering the intraerythrocytic cycle. The injected sporozoites typically take several hours to travel through dermal tissues and migrate across host cell barriers before they enter blood and lymphatic systems and are carried to the liver.²⁵ A molecular motor installed between the sporozoite plasma membrane and a double, inner membrane complex powers motility in this journey, whereas sporozoite surface proteins that are linked to this motor provide traction for gliding and crossing cellular barriers in tissue transit and invasion.²⁶^,²⁷

Invasion of sporozoites into hepatocytes takes place by a coordinated series of steps, including host cell contact, signaling events with discharge of calcium, release of ligands and processing molecules from apical organelles, and active entry of the sporozoite into an induced parasitophorous vacuole in the hepatocyte cytoplasm. The host tetraspanin molecule CD81 is important for sporozoite entry into hepatocytes.²⁸^,²⁹ Two recent studies have shown that the class B type 1 scavenger receptor SR-B1, a known co-receptor with CD81 for invasion of hepatocytes by hepatitis C virus (HCV), also promotes efficient Plasmodium infection of hepatocytes.³⁰^,³¹ A likely role for SR-B1 is the organization of CD81 into tetraspanin-enriched microdomains that are preferred membrane areas for sporozoite entry.³⁰ Because SR-B1 is vital in providing cholesterol to the hepatocyte by high-density lipoprotein (HDL)-cholesteryl ester uptake, its exploitation by Plasmodium and HCV represents the evolutionary selection of a dependable invasion pathway by these pathogens. SR-B1’s role in HDL-cholesteryl ester uptake and activation of the liver fatty acid carrier L-FABP also supports the transformation and growth requirements of the parasite inside the hepatocyte. Individual infected hepatocytes support the development of 10,000 to 30,000 merozoites, a process that is not associated with symptoms. All P. falciparum and P. malariae parasites complete their liver-stage development in about 1 to 2 weeks.³² P. vivax and P. ovale liver stages also can develop promptly or can remain latent as hypnozoites in the liver for months to years before emerging to produce relapses of malaria (see Fig. 276-2).

Once a merozoite³³ egresses by protease activity from its host hepatocyte (or from its host erythrocyte in the bloodstream cycle),³⁴ it engages loosely with an uninfected erythrocyte and then reorients so that its apical end faces the cell surface.³⁵ The merozoite then drives itself into the erythrocyte through a ring-shaped, electron-dense junction that moves from the front to back end of the merozoite by the power of an actin-myosin motor.³⁵ An envelope of invaginated membrane surrounds the merozoite as it enters, forming the parasitophorous vacuole once invasion is complete.³⁶ These steps of invasion are supported by cell-signaling events, energy-dependent migration, and discharge of contents from the rhoptries, micronemes, dense granules, and perhaps other apical compartments.³⁷ In P. falciparum, invasion can be supported by multiple different interactions between parasite molecules and erythrocyte surface molecules, including glycophorins.³⁸^,³⁹ Recent work has demonstrated the essential role of a ligand-receptor interaction between the P. falciparum RH5 (PfRH5) protein and the Ok blood group antigen, basigin.⁴⁰ A number of studies have also established a dependence of P. vivax merozoites on interaction with erythrocyte Duffy antigen receptor for chemokines (DARC),⁴¹^,⁴² but this may not be an absolute requirement considering that P. vivax infections occur in DARC-negative individuals, for example in Madagascar.⁴³

Within erythrocytes, merozoites develop from ring forms into trophozoites and then schizonts over 48 hours (P. falciparum, P. vivax, and P. ovale) or 72 hours (P. malariae). After breaking down their host cell membrane by enzymatic digestion, 24 to 32 merozoites enter the bloodstream and are each capable of infecting a new erythrocyte. Cycles of invasion and growth in erythrocytes produce a parasite biomass that enlarges rapidly, causing fever and leading to pathologic processes, such as erythrocyte loss (anemia) and sequestration of infected erythrocytes in microvascular beds (cerebral malaria).

Pathophysiology

The Malaria Paroxysm and General Considerations

Malaria presents as an acute febrile illness that is often but not always characterized by the classic malaria paroxysm: chills and rigors, followed by fever spikes up to 40° C (104° F), and then profuse sweating that can ultimately give way to extreme fatigue and sleep. Paroxysms last several hours, can occur with a regular periodicity coinciding with the synchronous rupture of blood schizonts, may alternate with relatively asymptomatic periods, and are associated with high levels of tumor necrosis factor (TNF).⁴⁴ Paroxysms can occur in 24-hour, tertian 48-hour, or quartan 72-hour cycles, or in other more complicated patterns.⁴⁵ TNF may originate from monocytes stimulated by glycosylphosphatidylinositol moieties or other substances released on schizont rupture.⁴⁶^,⁴⁷

Malaria can be acutely malignant and painful or more indolent and asymptomatic. It predisposes African children to bacteremia⁴⁸ and increases the morbidity and mortality associated with other diseases by stressing host systems and producing effects such as dehydration, anemia, and some degree of immune suppression. Malaria is tremendously debilitating and impedes economic development through its adverse effects on fertility, population growth, saving and investment, worker productivity, absenteeism, premature mortality, and medical costs.⁴⁹^,⁵⁰ A single episode of malaria has been estimated to result in a loss of 5 to 20 working days, and an agricultural family afflicted by malaria may be up to 60% less productive than a family without malaria.⁵¹

Plasmodium falciparum

P. falciparum malaria can be much more acute and severe than malaria caused by other Plasmodium species (Fig. 276-3). Although P. vivax can cause serious and fatal illness,⁵²^,⁵³ by far the largest fraction of deaths directly attributable to malaria are caused by severe complications of P. falciparum infection, including cerebral malaria, severe anemia, respiratory distress, renal failure, and severe malaria of pregnancy.⁵⁴^–⁵⁹ Important contributory factors include metabolic acidosis, hypoglycemia, and superimposed bacterial infections. Fatal P. falciparum infections are often associated with the failure of multiple organ systems.

An important feature of the pathogenesis of P. falciparum is the ability of its mature trophozoite and schizont forms to sequester in the deep venous microvasculature. This sequestration is promoted by a number of processes: the adherence of infected erythrocytes to endothelial cells ⁶⁰^–⁶² (Fig. 276-4F and G), rosetting—the binding of infected erythrocytes to uninfected erythrocytes⁶²^–⁶⁴ (see Fig. 276-4H), reduced erythrocyte deformability⁶⁵^,⁶⁶ (see Fig. 276-4C and D), and platelet-mediated clumping of infected erythrocytes.⁶⁷^,⁶⁸ In malaria of pregnancy, infected erythrocytes accumulate within the proteoglycan matrix of placental intervillous spaces.⁶⁹ P. falciparum–infected erythrocytes can thus accumulate throughout the body, including the heart,⁷⁰ lung,⁷¹ liver,⁷² brain,⁷¹^,⁷³^–⁷⁶ kidney,⁷⁷ intestine,⁷¹^,⁷³ dermis,⁷³ bone marrow,⁷⁸ and placenta.⁷⁹ Uninfected erythrocytes, monocytes, platelets, and deposits of thrombin and fibrin are often found in association with these infected erythrocytes.⁷¹^,⁷⁴^,⁷⁶^,⁷⁷

FIGURE 276-4 Morphologic features of Plasmodium parasites. A, Transmission electron micrograph of a P. knowlesi merozoite invading an erythrocyte (E) via its apical end, which contains rhoptries (R), micronemes (M), and dense granules (D). B, Transmission electron micrograph of an intraerythrocytic P. falciparum trophozoite containing cytosomes (C), digestive vacuole (DV), and crystalline hemazoin (H). Arrows identify numerous small electron-dense protrusions, termed “knobs,” on the surface of the host erythrocyte. C and D, Scanning electron micrographs demonstrate the effects of the malaria parasite on its host erythrocyte. Distension from the growth of the parasite P. falciparum converts the erythrocyte from a deformable biconcave disk (C) to a nondeformable cell (D) displaying knobs over its surface. E, Atomic force microscopic image of the surface of a P. falciparum–infected erythrocyte showing numerous knob structures. F, Transmission electron micrograph showing adherence via knobs (arrows) between a P. falciparum–infected erythrocyte and a host endothelial cell (EC) of a cerebral microvessel. G, Histologic section of brain tissue showing pigmented mature P. falciparum parasites sequestered in microvessels. H, Light microscopic image of rosetting, the binding of a P. falciparum–infected erythrocyte to multiple uninfected erythrocytes. (A from Fujioka H, Aikawa M. The malaria parasite and its life cycle. In: Wahlgren M, Perlmann P, eds. Malaria: Molecular and Clinical Aspects. Harwood Academic; 1999:19-55. B courtesy Hisashi Fujioka, Cleveland, OH. C and D from Aikawa M, Rabbege JR, Udeinya IJ, et al. Electron microscopy of knobs in Plasmodium falciparum–infected erythrocytes. J Parasitol. 1983;69:435-437. E courtesy James Dvorak and Takayuki Arie, Bethesda, MD. [From Atkinson CT, Aikawa M. Ultrastructure of malaria-infected erythrocytes. Blood Cells. 1990;16:351-368]. G courtesy Hisashi Fujioka, Cleveland, Ohio. H courtesy James Dvorak, Bethesda, MD.)

By sequestering in microvessels, P. falciparum may avoid filtration and destruction by the spleen and thus multiply to high densities.⁸⁰ The survival and propagation of parasites may be enhanced when they sequester in the low oxygen tension environment of postcapillary venules. Attachment points to endothelium have been shown by electron microscopy to be dense protrusions, termed “knobs,” on the surface of infected erythrocytes (see Fig. 276-4D and E), where antigenically variant cytoadherence proteins (P. falciparum erythrocyte membrane protein 1 [PfEMP-1]; see later) are anchored. Attachment at knobs (see Fig. 276-4F) supports cytoadherence in vitro and sequestration in vivo (see Fig. 276-4G).⁸¹^,⁸² Under flow conditions, cytoadherence events are reminiscent of leukocyte adhesion, involving distinct phases of tethering, rolling, and stable adhesion.⁸³

PfEMP-1 is central to malaria pathogenesis.⁸⁴ PfEMP-1 is a family of antigenically variant proteins encoded by the multicopy var gene family.⁸⁵ Approximately 60 different var genes are present in the haploid genome of each parasite, encoding PfEMP-1 variants with unique antigenic and cytoadherence properties.⁸⁶^,⁸⁷ A single PfEMP-1 variant is thought to be predominantly expressed on the surface of an individual infected erythrocyte,⁸⁸ whereas all others are silenced.⁸⁹ Switches in expression between individual members of the var gene family occur at an estimated rate of 2% to 18% per cell per generation⁹⁰^,⁹¹ and produce the antigenic variation in P. falciparum populations during the course of an infection. Broods of parasites infecting a human host may express several variants in their subpopulations.

The various PfEMP-1 proteins exposed on knobs have binding domains that adhere to host molecules, including CD36, intercellular adhesion molecule 1 (ICAM-1), thrombospondin, platelet endothelial cell adhesion molecule (PECAM/CD31),⁸³^,⁹²^–⁹⁵ chondroitin sulfate A (CSA),⁶⁹^,⁹⁶ and endothelial protein C receptor involved in the deadly sequestration of parasitized erythrocytes that leads to cerebral malaria.⁹⁷^–⁹⁹ In addition to the association of cerebral malaria with subsets of PfEMP-1 variants that adhere to brain endothelium, other pathologic conditions have also been linked to particular PfEMP-1 variants and host receptors.⁶⁰^,¹⁰⁰^–¹⁰⁵ CD36 is an important cytoadherence receptor expressed on microvascular endothelium, as well as on monocytes and platelets, and is thought to mediate the sequestration of parasites as well as the host immune response to infection.¹⁰⁶ Infected erythrocytes that bind CSA expressed by syncytiotrophoblasts sequester selectively in placental tissue and are responsible for malaria of pregnancy.⁶⁹

Some PfEMP-1 variants are also important parasite ligands in rosetting¹⁰⁷ because they can adhere to complement receptor 1 (CR1)¹⁰⁸ and blood group A antigen¹⁰⁹ on uninfected erythrocytes. A human CR1 polymorphism that reduces P. falciparum rosetting was found in one study to protect against severe malaria¹¹⁰; data from other studies of rosetting and disease severity have, in some cases, shown an association¹¹¹^–¹¹⁵ and in others have not.¹¹⁶^,¹¹⁷ PfEMP-1 variants that bind to glycoprotein CD36 on the surface of platelets are also thought to play an important role in the platelet-mediated clumping of infected erythrocytes.⁶⁷

High parasite densities,¹¹⁸ increased parasite multiplication rates,¹¹⁹ and evidence of high parasite biomass (e.g., intraleukocytic pigment, mature trophozoites, and schizonts) on peripheral blood smears are associated with increased severity of malaria and death.¹²⁰^–¹²² P. falciparum can infect erythrocytes of all ages,¹²³ promoting heavy parasite burdens; P. vivax selectively infects reticulocytes¹²⁴^,¹²⁵ and thus does not achieve high densities in the peripheral blood.

Cerebral Malaria

The classic histopathologic finding of fatal cerebral malaria is the intense sequestration of infected erythrocytes in cerebral microvessels (see Fig. 276-4G), often accompanied by “ring” hemorrhages, perivascular leukocyte infiltrates, thrombin deposition, activated platelets,⁷⁵^,¹²⁶^–¹²⁸^,¹²⁹^,¹³⁰ and immunohistochemical evidence for endothelial cell activation.⁷⁴^,¹³¹^,¹³² In one autopsy series of patients who died from cerebral malaria, 94% of brain microvessels contained adherent infected erythrocytes, compared with 13% of patients who died from noncerebral malaria.¹³³ In another study, 7 of 31 (24%) African children who received a clinical diagnosis of cerebral malaria were found at autopsy to have nonmalarial causes of coma, underscoring the possibility that other illnesses may mimic the cerebral malaria presentation in areas where incidental parasitemia is common.¹²⁸

Sequestration of infected erythrocytes stimulates the local production of inflammatory cytokines, such as TNF, elevated levels of which may correlate with disease severity.¹³⁴^–¹³⁶ These cytokines and other inflammatory mediators also upregulate adhesion molecules, such as ICAM-1, in the cerebral microvasculature,¹³⁷^,¹³⁸ which may lead to further sequestration of infected and uninfected erythrocytes, leukocytes, and activated platelets.¹²⁶ Impaired nitric oxide bioavailability may also contribute to endothelial dysfunction¹³⁹ by increasing microvascular tone, endothelial cell adhesion molecule expression, cytokine production, and infected erythrocyte sequestration.¹⁴⁰ These processes may cause varying degrees of functional obstruction and consequently impair local delivery of oxygen and glucose. However, obstruction by infected erythrocytes and other blood elements does not generally produce neurologic sequelae akin to those that follow the physical occlusion in thrombotic stroke because most patients with cerebral malaria who recover can do so rapidly within 48 hours and without such consequences. Systemic sequestration of metabolically active parasites, blood cells, and platelets likely contributes to the metabolic acidosis and thrombocytopenia commonly seen in severe malaria. Metabolic acidosis, hypoglycemia, hyperpyrexia, and nonconvulsive status epilepticus can contribute significantly to the cerebral malaria presentation, as suggested by the rapid clinical improvement of some patients after fluid resuscitation, blood transfusion, dextrose infusion, fever reduction, and anticonvulsant therapy in addition to antimalarial treatment.¹⁴¹^–¹⁴⁴

Hypoglycemia

Hypoglycemia in malaria can cause coma and convulsions and thus may contribute substantially to the morbidity and mortality associated with cerebral malaria.⁵⁴ The pathophysiologic mechanisms of hypoglycemia in children and adults seem to be different. In children, insulin levels are appropriate and hypoglycemia is associated with impaired hepatic gluconeogenesis and increased consumption of glucose by hypermetabolic peripheral tissues.¹⁴³^,¹⁴⁵^–¹⁴⁸ Large amounts of glucose are also consumed by intraerythrocytic parasites.¹⁴⁹ In adults, hypoglycemia is often associated with hyperinsulinemia,¹⁵⁰ which may result from pancreatic islet cell stimulation by parasite-derived factors and/or parenteral quinine or quinidine therapy.¹⁵¹ Depletion of liver glycogen stores after decreased food intake during the prodromal period may also contribute to hypoglycemia.

Anemia

The pathophysiology of malarial anemia is multifactorial and complex.¹⁵²^–¹⁵⁴ The intravascular lysis and phagocytic removal of infected erythrocytes¹⁵⁵ contribute to anemia but do not account for the dramatic reductions in erythrocyte mass that can accompany acute P. falciparum malaria episodes. Additional processes have therefore been implicated in the pathogenesis of malarial anemia. Excess removal of uninfected erythrocytes may account for up to 90% of erythrocyte loss¹⁵⁶ and may be mediated by processes (e.g., oxidative stress) that accelerate the senescence and reduce the deformability of erythrocytes. The contribution of impaired erythropoietic responses to malarial anemia is significant and probably involves general processes also found in other diseases. Release of inflammatory cytokines (e.g., TNF) are associated with impaired production of erythropoietin,¹⁵⁷^,¹⁵⁸ decreased responsiveness of erythroid progenitor cells to adequate levels of erythropoietin,¹⁵⁹^,¹⁶⁰ and increased erythrophagocytic activity.¹⁶¹ These pathogenic processes account for the normochromic/normocytic anemia seen in malaria, and explain the notable absence of a robust reticulocyte response. Although microcytosis and hypochromia are seen in malaria, these findings are often attributable to thalassemias and iron deficiency in endemic areas. Bacteremia, nutritional deficits (e.g., vitamin A and B₁₂ deficiencies), concomitant infections (e.g., hookworm and Schistosoma), and genetic polymorphisms (glucose-6-phosphate dehydrogenase [G6PD] deficiency) have also been associated with greater degrees of anemia in malaria episodes,¹⁶² presumably by lowering the baseline from which hemoglobin levels acutely decline. In endemic areas where chloroquine resistance is prevalent, the inability of young children to clear their parasitemias with chloroquine contributes to their higher baseline prevalence of anemia when compared with children treated with more effective drugs.¹⁶³

Pulmonary Edema and Respiratory Distress

The most significant pulmonary manifestation directly attributable to P. falciparum is noncardiogenic pulmonary edema.¹⁶⁴^,¹⁶⁵ Sequestration of infected erythrocytes in the lungs is thought to initiate regional production of inflammatory cytokines that increase capillary permeability, leading sequentially to pulmonary edema, dyspnea, hypoxia, acute lung injury, and acute respiratory distress syndrome (ARDS).¹⁶⁶^,¹⁶⁷ Pulmonary edema is common with severe malaria in adults but infrequent in children, and it is not associated with pleural effusion. Iatrogenic fluid overload and acute renal failure may contribute to the development or worsening of pulmonary edema. Although pulmonary edema usually occurs after other features of severe disease (e.g., coma, acute renal failure) become manifest, it may occur at any time during the clinical course, even when the patient appears to be recovering on antimalarial therapy. Dyspnea and increased respiratory rate are features of impending pulmonary edema and often precede other clinical (e.g., use of accessory muscles of respiration) and radiologic signs (e.g., generalized increase in interstitial markings).

Pulmonary manifestations of deep breathing and respiratory distress associated with severe malaria may also arise from metabolic acidosis,⁵⁵ severe acute respiratory infections,¹⁴⁷ sepsis-related ARDS, aspiration (especially with diminished consciousness or convulsions), and nosocomial pneumonia. Cerebral pathologic processes may result in abnormal breathing patterns including Cheyne-Stokes respirations and respiratory failure.¹⁶⁸

Metabolic (Lactic) Acidosis

Metabolic acidosis is a common feature of severe malaria and is associated with significant lactic acidemia in up to 85% of cases. Metabolic acidosis is principally caused by reduced delivery of oxygen to tissues, from the combined effects of anemia (decreased oxygen-carrying capacity), sequestration (microvascular obstruction), and hypovolemia (reduced perfusion) resulting from fluid losses caused by fever, decreased oral intake, vomiting, and diarrhea.¹⁶⁹ These effects produce a shift from aerobic to anaerobic metabolism and cause lactate levels to increase.¹⁷⁰ The following factors may also contribute to metabolic acidosis: production of lactate by anaerobic glycolysis in sequestered parasites;¹⁷¹ reduction of hepatic blood flow, leading to diminished lactate clearance;¹⁷²^,¹⁷³ induction of lactate production by TNF and other proinflammatory cytokines;¹⁷⁴ impairment of renal function;¹⁷² and ingestion of exogenous acids (e.g., salicylate) or unknown constituents of traditional herbal remedies for fever.¹⁷⁵

Malaria of Pregnancy

Placental malaria results in maternal morbidity and mortality, intrauterine growth retardation, premature delivery, low birth weight, and increased newborn mortality.¹⁷⁶^–¹⁷⁸ Selective accumulation of infected erythrocytes in the placenta involves their interaction with syncytiotrophoblastic CSA,⁶⁹ which is possibly complemented by interactions with other molecules, such as hyaluronic acid and immunoglobulins.¹⁷⁹^–¹⁸¹ This is in contrast to the sequestration of infected erythrocytes in the systemic microvasculature, where CD36 is the major endothelial receptor. Parasites that accumulate in the placenta express PfEMP-1 variants that bind CSA¹⁸²^,¹⁸³ but not CD36.¹⁸⁴ Evidence suggests that women experiencing a malaria episode from CSA-binding parasites during their first pregnancy lack immunity to the PfEMP-1 antigenic variants presented by these strains and, despite immunity to CD36-binding variants from previous infections, are highly susceptible to the new placental infection. Placental malaria in subsequent pregnancies is typically less severe than in the first pregnancy,¹⁸⁵ presumably because of a woman’s previous experience with CSA-binding parasites.

Plasmodium vivax and Plasmodium ovale

Infections with P. vivax and P. ovale can be considered similar to each other from a clinical perspective. P. vivax infections can be tremendously debilitating and are sometimes associated with serious complications, including acute lung injury¹⁸⁶^,¹⁸⁷ and splenic pathologies.¹⁸⁸^,¹⁸⁹ Splenic rupture has been associated with acute and chronic infections and can occur spontaneously or with minor trauma, including manual examination of the spleen. Although more commonly associated with P. vivax malaria, splenic rupture has been associated with all four human malaria parasites. Anemia is frequently observed as a consequence of acute or chronic infections, or as a result of repeated acute infections.¹⁵⁵ Suppressed erythrocyte production and hemolysis of both infected and uninfected erythrocytes have been implicated in the pathogenesis of P. vivax malarial anemia. Although not often fatal, P. vivax infections have recently been associated in Papua New Guinea and Indonesia with severe disease manifestations, including cerebral malaria, severe anemia, and respiratory distress.⁵²^,⁵³^,¹⁹⁰

P. vivax merozoites selectively invade reticulocytes.¹²⁵ Because these cells account for only a small proportion of the total erythrocyte mass, parasitemias in P. vivax infections are usually less than 1%. Recent evidence suggests that P. vivax can cytoadhere to lung endothelial cells¹⁹¹ and can cause lung injury by sequestering in the pulmonary microvasculature.¹⁹² P. vivax parasites may avoid splenic entrapment by increasing rather than decreasing erythrocyte deformability.¹⁹³