The diagnostic histopathologic features of ocular malaria

Update on pathology of ocular parasitic disease

Parasites are a group of eukaryotic organisms that may be free-living or form a symbiotic or parasitic relationship with the hosts. Consisting of over 800,000 recognized species, parasites may be unicellular (Protozoa) or multicellular (helminths and arthropods). The association of parasites with human population started long before the emergence of civilization. Parasitic zoonotic diseases are prevalent worldwide including India. Appropriate epidemiological data are lacking on existing zoonotic parasitic diseases, and newer diseases are emerging in our scenario. Systemic diseases such as cysticercosis, paragonimiasis, hydatidosis, and toxoplasmosis are fairly common. Acquired Toxoplasma infections are rising in immune-deficient individuals. Amongst the ocular parasitic diseases, various protozoas such as Cystoidea, trematodes, tissue flagellates, sporozoas etc. affect humans in general and eyes in particular, in different parts of the world. These zoonoses seem to be a real health related problem globally. Recent intensification of research throughout the world has led to specialization in biological fields, creating a conducive situation for researchers interested in this subject. The basics of parasitology lie in morphology, pathology, and with recent updates in molecular parasitology, the scope has extended further. The current review is to address the recent update in ophthalmic parasites with special reference to pathology and give a glimpse of further research in this field.

A Review of Plasmodium coatneyi-Macaque Models of Severe Malaria

Malaria remains one of the most significant public health concerns in the world today. Approximately half the human population is at risk for infection, with children and pregnant women being most vulnerable. More than 90% of the total human malaria burden, which numbers in excess of 200 million annually, is due to Plasmodium falciparum. Lack of an effective vaccine and a dwindling stockpile of antimalarial drugs due to increased plasmodial resistance underscore the critical need for valid animal models. Plasmodium coatneyi was described in Southeast Asia 50 years ago. This plasmodium of nonhuman primates has been used sporadically as a model for severe malaria, as it mimics many of the pathophysiologic features of human disease. This review covers the reported macroscopic, microscopic, ultrastructural, and molecular pathology of P. coatneyi infection in macaques, specifically focusing on the rhesus macaque, as well as describing the critical needs still outstanding in the validation of this crucial model of human disease.

Contrasting pediatric and adult cerebral malaria: the role of the endothelial barrier

Malaria affects millions of people around the world and a small subset of those infected develop cerebral malaria. The clinical presentation of cerebral malaria differs between children and adults, and it has been suggested that age-related changes in the endothelial response may account for some of these differences. During cerebral malaria, parasites sequester within the brain microvasculature but do not penetrate into the brain parenchyma and yet, the infection causes severe neurological symptoms. Endothelial dysfunction is thought to play an important role in mediating these adverse clinical outcomes. During infection, the endothelium becomes activated and more permeable, which leads to increased inflammation, hemorrhages, and edema in the surrounding tissue. We hypothesize that post-natal developmental changes, occurring in both endothelial response and the neurovascular unit, account for the differences observed in the clinical presentations of cerebral malaria in children compared with adults.

Perfusion abnormalities in children with cerebral malaria and malarial retinopathy

BACKGROUND

In patients with cerebral malaria (CM), retinal angiography allows the study of infected central nervous system microvasculature in vivo. We aimed to examine retinal perfusion in children with CM by use of fluorescein angiography to investigate the pathophysiology of CM.

METHODS

We performed fluorescein angiography on children with CM admitted to Queen Elizabeth Central Hospital, Malawi. We related angiograms to funduscopic findings.

RESULTS

Fluorescein angiography was performed for 34 patients with CM, and impaired perfusion was identified in 28 (82%). Areas of capillary nonperfusion (CNP) were seen in 26 patients (76%). Multiple, scattered areas of CNP were typical and topographically matched to retinal whitening. Larger retinal vessels were occluded in 9 patients (26%) who had associated ischemia. These vessels appeared white on ophthalmoscopy. Intravascular abnormalities were seen in 9 patients (26%), including filling defects and mottling of the blood column. Limited fluorescein leakage occurred in 15 patients (44%) and was not related to angiographic intravascular abnormalities or visible vessel discoloration.

CONCLUSIONS

Impaired perfusion occurs in the retinal microvasculature of most children with CM. This is evidence for hypoxia and ischemia as important components in the pathogenesis of CM. Vessel occlusion and filling defects are likely to be due to sequestration of infected erythrocytes. Interventions which improve perfusion or limit hypoxic injury may be beneficial in CM.

Complement factor D, albumin, and immunoglobulin G anti-band 3 protein antibodies mimic serum in promoting rosetting of malaria-infected red blood cells

Rosetting of Plasmodium falciparum-infected red blood cells (parasitized RBC [pRBC]) with uninfected RBC has been associated in many studies with malaria morbidity and is one form of cytoadherence observed with malarial parasites. Rosetting is serum dependent for many isolates of P. falciparum, including the strains FCR3S1.2 and Malayan Camp studied here. We identified the three naturally occurring components of sera which confer rosetting. Complement factor D alone induced 30 to 40% of de novo rosetting. Its effect was additive to that of 0.5 mg/ml albumin and to that of 15 ng/ml of naturally occurring antibodies to the anion transport protein, band 3. The three components together mediated rosetting as effectively as 10% serum. De novo rosetting experiments showed that naturally occurring anti-band 3 antibodies as well as factor D were effective only when added to pRBC. Factor D appeared to cleave a small fraction of a protein expressed on the surface of pRBC.

Retinal haemorrhage in vivax malaria

Retinal haemorrhage is often observed in patients with Plasmodium falciparum, especially when combined with cerebral malaria. However, few cases of retinopathy have been reported in P. vivax malaria. Benign tertian malaria has re-emerged among soldiers in the South Korean demilitarized zone since 1993. We report an indigenous case of retinal haemorrhage caused by P. vivax and review the relevant literature.

Correlation of retinal haemorrhages with brain haemorrhages in children dying of cerebral malaria in Malawi

Retinal haemorrhages increase in number with severity of Plasmodium falciparum malaria and occur in 35-40% of children with cerebral malaria. We performed clinical retinal examinations and histopathological examinations of retina, and parietal and cerebellar sections of the brains, in 33 children in Malawi who died with cerebral malaria, severe malaria anaemia, or coma of other causes. Haemorrhages were counted in a standardized fashion: the Spearman correlation coefficient between the number of haemorrhages in retina and brain was 0.741 for parietal tissue and 0.703 for cerebellar (P < 0.01 for both). Severity of haemorrhage in the retina correlates well with that in the brain. Retinal examination in cerebral malaria is a useful tool in predicting some of the pathophysiological processes occurring in the brain.

Compromised blood-nerve barrier, astrogliosis, and myelin disruption in optic nerves during fatal murine cerebral malaria

We examined the optic nerve, as an analogous tissue to brain white matter, to assess possible relationships between changes in the blood-nerve barrier, axonal integrity, and astrocyte morphology in the central nervous system during fatal murine cerebral malaria (FMCM). In the FMCM model, namely, CBA mice infected with Plasmodium berghei ANKA, neurological symptoms begin around day 5 post-inoculation (p.i.) and mice become increasingly ill by day 7 p.i., at which time they lapse into coma and die. Using intravascular perfusion with horseradish peroxidase combined with light and electron microscopy, and GFAP immunohistochemistry, the optic nerves in malaria-infected mice were found to display i) breakdown of the blood-nerve barrier, detectable as early as day 3 p.i. (about 2 days before the onset of neurological symptoms) increasing to peak severity by day 7 p.i.; ii) monocytosis, vascular congestion, and monocyte adherence to the endothelium in the microvasculature during the later stages of the disease process; iii) an increased incidence of patchy axonal demyelination and degeneration, mostly associated with vascular changes and astrogliosis, beginning at day 5 p.i. and more evident by day 7 p.i.; and iv) an increased intensity of GFAP immunostaining, detectable from day 3 p.i. and peaking at day 7 p.i. These optic nerve changes were always seen in the infected individuals, though they varied in intensity. The temporal and anatomical coincidence between the compromised blood-nerve barrier, monocyte adherence to the vascular endothelium, astrocyte changes, neuronal degeneration, and demyelination in the optic nerve in FMCM suggests that these factors are mechanistically inter-related. These findings are consistent with the proposed immunopathological nature of FMCM and provide further evidence for the pivotal role of the CNS microvasculature in the disease process. This is the first investigation of involvement of the optic nerve in FMCM and the first demonstration, to our knowledge, of loss of axonal viability in this condition in any CNS tissue. The observed demyelination is consistent with reports by other workers on such changes in the brain in human cerebral malaria.

Ocular malaria. A clinical and histopathologic study

PURPOSE

Clinical and histopathologic findings of ocular lesions in malaria rarely have been described. This study reports lesions in three patients with malaria, with a histopathologic study of eyes obtained at autopsy of one of these patients.

METHODS

Various ocular lesions were documented in three patients with malarial infection, with histopathologic study of one patient. In all three patients, the diagnosis of malaria was confirmed by the demonstration of malarial parasites in peripheral smears and by fluorescent microscopy of acridine orange-stained buffy coat preparations of venous blood.

RESULTS

Multiple superficial blotchy retinal hemorrhages over the posterior pole were seen in the first patient, whereas acute bilateral panuveitis and secondary glaucoma were seen in the second, which on resolution showed multiple blotchy superficial retinal hemorrhages with perivasculitis. The third patient had cerebral malaria and was found to have subconjunctival and retinal hemorrhages. This patient died of pulmonary thromboembolism, and the eyes were obtained at autopsy. On gross examination, there were multiple retinal hemorrhages in the posterior pole. Histopathologic study showed cytoadherence of parasitized erythrocytes as well as schizonts and gametocytes of Plasmodium vivax within the retinal and choroidal blood vessels.

CONCLUSION

The authors' findings suggest that patients with unexplained blotchy retinal hemorrhages should be investigated for malarial infection, especially if they reside or have travelled in endemic areas.

Novel fibrillar structure confers adhesive property to malaria-infected erythrocytes

Infections with the malaria parasite Plasmodium falciparum are characterized by sequestration of erythrocytes infected by mature forms of the parasite. Sequestration seems critical for the survival of the parasite, but may lead to excessive binding in the microvasculature and death of the human host. We report here that a novel electrondense fibrillar structure, containing immunoglobulins M or M and G, is found at the surface of infected erythrocytes that adhere to host cells. In cases of cerebral malaria, fibrillar strands are also seen in the microvasculature at autopsy. Our findings may explain the adhesive mechanism by which malaria-infected erythrocytes cause the vascular obstruction seen in complicated malaria infections.

Pattern of uveitis in a referral uveitis clinic in India

This report describes a retrospective study of all new patients in our uveitis clinic between January 1992 and December 1994, undertaken to identify the pattern of uveitis in the Indian subcontinent. A standard clinical protocol, and the naming-meshing system with tailored laboratory investigations were used to arrive at a final uveitic diagnosis. Uveitis comprised 1.5% of new cases seen at the centre. Out of 1,273 uveitis cases, anterior uveitis was the most common type (39.28%), followed by posterior uveitis (28.75%), intermediate uveitis (17.44%), and panuveitis (14.53%). The most commonly affected age group were patients in their forties (23.57%). Uveitis was less common in children below 10 years (3.61%) and in adults over 60 years of age (6.44%). Men (62.21%) were more commonly affected than women (37.79%). Aetiology remained undetermined in 59.31% of cases. Anterior uveitis was most commonly idiopathic (58.6%). The most common cause of posterior uveitis was toxoplasmosis (27.87%), and that of panuveitis was the Vogt-Koyanagi-Harada syndrome (21.08%). A higher incidence of microbiologically proven tubercular uveitis (5 cases), and uveitis due to live intraocular nematode (4 cases), and malaria (1 case), were seen, in contrast to other studies. Only 2 cases of AIDS with ocular lesions were seen. This paper reveals the pattern of uveitis seen at a major referral eye institute in India.

Redistribution and degeneration of retinal astrocytes in experimental murine cerebral malaria: relationship to disruption of the blood-retinal barrier

To determine whether astrocytes play a critical role in the pathogenesis of experimental murine cerebral malaria (EMCM), we examined changes in astrocyte morphology and distribution, using retinal wholemounts, in three models: a fatal cerebral malaria (CM) model, in which mice die showing cerebral symptoms; a "resolving" model, in which mice exhibit mild cerebral symptoms, but then recover; and a non-CM model, in which cerebral symptoms are not seen. In the fatal model, retinal astrocytes lost their even distribution from day 3 post-inoculation (p.i.) with malaria parasites, progressing to gliosis (day 5 p.i.), well before the onset of cerebral symptoms on day 6-7 p.i. At the terminal stage of the disease there was a loss of astrocyte processes contacting retinal vessels, often along vessel segments containing adherent monocytes. These features occurred in a mild form in the resolving model and were absent in the non-CM models. To investigate the mechanisms underlying these astrocytic changes, we carried out two experimental manipulations. Firstly, since dexamethasone ameliorates cerebral complications in the fatal CM model, the astrocytic response was monitored after dexamethasone treatment on days 0 and 1 p.i., or days 3 and 4 p.i. Second, to determine whether increased blood-retinal barrier (BRB) permeability initiates the astrocyte changes, breakdown of the BRB was induced experimentally by intra-carotid injection of arabinose and astrocyte morphology and distribution were examined 12, 24, and 48 h later. Retinal astrocytes in both the dexamethasone- and the arabinose-treated groups showed loss of even astrocyte distribution but no loss of astrocyte ensheathment of vessels. It is concluded that: i) astrocytes are involved in the pathogenesis of EMCM, since these changes are only prominent in the fatal model and occur substantially before the onset of cerebral symptoms; ii) the initial changes in astrocyte distribution may be a consequence of the increase in BRB permeability; and iii) the immune response triggered by the malaria parasite may be responsible for the loss of astrocyte ensheathment of vessel segments.

Plasmodium falciparum rosetting is associated with malaria severity in Kenya

Rosette formation in 154 fresh Plasmodium falciparum isolates from Kenyan children with mild (n = 54), moderate (n = 64), or severe (n = 36) malaria was studied to determine whether the ability to form rosettes in vitro is correlated with malaria severity. There was a wide distribution of rosette frequencies within each clinical category; however, a clear trend towards higher rosette frequency with increasing severity of disease was seen, with the median rosette frequency of the mild-malaria group (1%; range, 0 to 82%) being significantly lower than those of the moderate-malaria group (5%; range, 0 to 45%; Mann-Whitney U test, P < 0.02) and the severe-malaria group (7%; range, 0 to 97%; Mann-Whitney U test, P < 0.003). Within the severe-malaria category there was no difference in rosetting among isolates from cerebral malaria patients or those with other forms of severe malaria. We also examined the ABO blood groups of the patients from whom isolates were obtained and found that isolates from group O patients (median rosette frequency, 2%; range 0 to 45%) rosetted less well than those from group A (median, 7%; range 0 to 82%; Mann-Whitney U test, P < 0.01) or group AB (median, 11%; range 0 to 94%; Mann-Whitney U test, P < 0.03). We therefore confirm that rosetting is associated with severe malaria and provide further evidence that rosetting is influenced by ABO blood group type. Whether rosetting itself plays a direct role in the pathogenesis of severe malaria or is a marker for some other causal factor remains unknown.