Medical Parasitology MCB336 Past Paper PDF 2024

Summary

This document is an overview of medical parasitology, specifically focusing on protozoa, such as amoebas (Entamoeba species) and ciliates (Balantidium coli). It covers their structure, geographical distribution, and transmission methods. The document also touches on the disease symptoms and methods of diagnosis, as well as treatment protocols for amoebiasis and other protozoan infections.

Full Transcript

MEDICAL PARASITOLOGY MCB336

PROTOZOA
Protozoa of medical Importance: structure, geographical distribution, source of
infection/transmission, life cycle, disease.

Protozoans are usually single-celled and heterotrophic (using organic carbon as a
source of energy), belonging to any of the major lineages of protists and like most
protists, typically microscopic. All protozoans are eukaryotes and therefore possess a
“true,” or membrane-bound, nucleus. They also are non-filamentous and are confined to
moist or aquatic habitats, being ubiquitous in such environments worldwide.
Features of protozoans
The protozoans are unified by their heterotrophic mode of nutrition, meaning that these
organisms acquire carbon in reduced form from their surrounding environment. Many
protozoans either perform photosynthesis themselves or benefit from the
photosynthetic capabilities of other organisms. Protozoans are motile; nearly all
possess flagella, cilia, or pseudopodia that allow them to navigate their aqueous
habitats. Protozoans are also strictly non-multicellular and exist as either solitary cells
or cell colonies.
Protozoa are unicellular eukaryotes that form an entire Kingdom. Protozoa are basically
grouped into five based on their means of locomotion and mode of reproduction. They
are: Amoeba, Ciliates, Flagellates, Sporozoa and Microspora.
AMOEBA (Sarcodina)
They are typically amoboid and use pseudopodia to move or protoplasmic flow. The
species of human medical importance are Entamoeba, Naegleria and Acanthoamoeba.
They have no defined shape and extend one or many lobose pseudopodia.
Entamoeba are pseudopod forming tiny protozoan parasite of man and animals in the
subphylum Sarcodina. About seven species have been recovered from the gut of man.
They are E. histolytica, E. dispar, E. moshkovskii, E. coli, E. polecki and E. hartmanni. E.
gingivalis is recovered from the buccal cavity of man. E. histolytica is the only known
pathogenic species of the human intestinal amoebae. E. dispar, E. hartmanni, E.
coli and E. polecki are commensals found in the large intestine. The large trophozoite
and cyst of E. coli can be identified by the splinter-like chromatid bodies in its cytoplasm,
and by the fact that its cysts can possess up to eight nuclei.
Structure
Entamoeba cells are small, with a single nucleus and typically a single lobose
pseudopod taking the form of a clear anterior bulge. They have a simple life cycle. The
trophozoite (feeding-dividing form) is approximately 10-20μm in diameter and feeds
primarily on bacteria. It divides by simple binary fission to form two smaller daughter
cells. Almost all species form cysts, the stage involved in transmission (with the
exception of Entamoeba gingivalis). Depending on the species, these can have one, four
or eight nuclei and are variable in size; which help in species identification. Uni-
nucleated trophozoites convert into cysts in a process called encystation.
Geographic Distribution
Pathogenic Entamoeba species occur worldwide and are frequently recovered from
fresh water contaminated with human faeces. The majority of amoebiasis cases occur
in developing countries where sanitation and hygiene are poor; places like day-care,
prisons and psychiatrics. Risk groups include men who have sex with men, travellers,
recent immigrants, immunocompromised persons, and institutionalized populations.

Diagram of Trophozoite of Entamoeba histolytica (Two trophozoites have
ingested erythrocytes, and all 3 have nuclei with small, centrally located
karyosomes).

Amoebiasis
Amoebiasis is caused by E. histolytica, a protozoan that is found worldwide. Another
species of amoeba, E. dispar, has been reported as a potential cause of amoebic liver
abscess. The highest prevalence of amoebiasis is in developing countries where
barriers between human faeces and food and water supplies are inadequate. Although
most cases of amoebiasis are asymptomatic, dysentery and invasive extraintestinal
disease can occur. Amoebic liver abscess is the most common manifestation of
invasive amoebiasis, but other organs can also be involved, including pleuropulmonary,
cardiac, cerebral, renal, genitourinary, peritoneal, and cutaneous sites.
The National Institute of Allergy and Infectious Diseases (NIAID) has classified E.
histolytica as a category B biodefense pathogen because of its low infectious dose,
environmental stability, resistance to chlorine, and ease of dissemination through
contamination of food and water supplies. Only 1–100 cysts are required to
cause amoebic dysentery in animal models, an infectious dose comparable to the
notoriously contagious Shigella sp.

Transmission
E. histolytica is transmitted through the ingestion of the cystic form (infective stage) of
the protozoa. Viable in the environment for weeks to months, cysts can be found in
faecal contaminated soil, fertilizer, or water or on the contaminated hands of food
handlers. Faecal-oral transmission can also occur in the setting of anal sexual practices
or direct rectal inoculation through colonic irrigation devices.

Life cycle
Amoebiasis is the disease caused by E. histolytica and is composed of two main
syndromes: dysentry and liver abscesses. Cysts and trophozoites are passed in faeces. Cysts are typically found in formed stool, whereas trophozoites are typically found
in diarrhoeal stool. Infection with Entamoeba histolytica (and E. dispar) occurs through
ingestion of mature cysts from faecally contaminated food, water, or
hands. Exposure to infectious cysts and trophozoites in faecal matter during sexual
contact may also occur. Excystation occurs in the terminal ileum or colon or small
intestine, resulting in trophozoites (invasive form) which are released, and they
migrate to the large intestine. Trophozoites may remain confined to the intestinal lumen
(A: noninvasive infection) with individuals continuing to pass cysts in their stool
(asymptomatic carriers). The trophozoites can penetrate and invade the colonic
mucosal barrier, leading to tissue destruction, secretory bloody diarrhoea, and colitis
resembling inflammatory bowel disease (B: intestinal disease), or blood vessels,
reaching extraintestinal sites such as the liver, brain, and lungs (C: extraintestinal
disease) through the portal circulation. The liver is the most common site of
extraintestinal amoebiasis. Trophozoites multiply by binary fission and produce cysts
, and both stages are passed in the faeces. The life cycle of the amoeba is
completed when trophozoites in the large intestine encyst and are excreted in the
faeces of the host. Cysts can survive days to weeks in the external environment and
remain infectious in the environment due to the protection conferred by their walls.
Trophozoites passed in the stool are rapidly destroyed once outside the body, and if
ingested would not survive exposure to the gastric environment.
E. histolytica may be observed with the ingested red blood cells
(erythrophagocytosis); E. dispar may occasionally be seen with ingested erythrocytes as
well, although its capacity for erythrophagocytosis is much less than that of E.
histolytica.
Clinical Presentation
The majority of infections restricted to the lumen of the intestine (“luminal amoebiasis”)
are asymptomatic. Amoebic colitis, or invasive intestinal amoebiasis, occurs when the
mucosa is invaded. Symptoms include severe dysentery and associated complications.
Severe chronic infections may lead to further complications such as peritonitis,
perforations, and the formation of amoebic granulomas (amoeboma).
Amoebic liver abscesses are the most common manifestation of extraintestinal
amebiasis. Pleuropulmonary abscess, brain abscess, and necrotic lesions on the
perianal skin and genitalia have also been observed.

Treatment: Metronidazole and tinidazole.
Life cycle of Entaemoba histolytica

CILIATES (Ciliophora)
Ciliate, or ciliophora, are members of the protozoan phylum Ciliophora, with about 8,000
species. Ciliates are single-celled organisms that, at some stage in their life cycle,
possess cilia, short hairlike organelles used for locomotion and food gathering.
Ciliates have one or more macronuclei and from one to several micronuclei. The
macronuclei control metabolic and developmental functions; the micronuclei are
necessary for reproduction. Reproduction is typically asexual, although sexual exchange
occurs as well. Asexual replication is usually by transverse binary fission or by budding.
Sexual phenomena include conjugation (genetic exchange between individuals) and
autogamy (nuclear reorganization within an individual). Sexual reproduction does not
always result in an immediate increase in numbers; however, conjugation is often
followed by binary fission. The only human parasite in this group is Balntidium coli,
which is a giant intestinal ciliate of human and pigs.

Causal Agents
Balantidium coli, a large ciliated protozoan, is the only ciliate known to be capable of
infecting humans. It is often associated with swine, the primary reservoir host. Humans
can also be reservoirs, and other potential animal hosts include rodents and nonhuman
primates.
Morphology
The organism is surrounded by cilia. B. coli has two developmental stages,
a trophozoite stage and a cyst stage. In trophozoites, the two nuclei are visible. The
macronucleus is long and sausage-shaped, and the spherical micronucleus is nested
next to it, often hidden by the macronucleus. The opening, known as the peristome, at
the pointed anterior end leads to the cytostome, or the mouth. The cysts are smaller
than the trophozoites and are round and have a tough, heavy cyst wall made of one or
two layers. Usually only the macronucleus and sometimes cilia and contractile
vacuoles are visible in the cyst, however, both nuclei are present because nuclear
multiplication does not occur when the organism is a cyst. Living trophozoites and
cysts are yellowish or greenish in color.
Morphology of Balantidium coli

Balantidiasis

Epidemiology
B. coli occurs worldwide. Because pigs are the primary reservoir, human infections
occur more frequently in areas where pigs are raised, sanitation is inadequate, and
especially among those that are in close contact with swine. The disease is considered
to be rare and occurs in less than 1% of the human population. The disease poses a
problem mostly in developing countries, where water sources may be contaminated
with swine or human feces.
Transmission
Balantidium is the only ciliated protozoan known to infect humans. Balantidiasis is
a zoonotic disease and is acquired by humans through the faecal-oral route from the
normal host, the domestic pig, where it is asymptomatic. Contaminated water is the
most common mechanism of transmission.
B. coli life cycle
Infection occurs when a host ingests a cyst, which usually happens during the
consumption of contaminated water or food. Once the first cyst is ingested, it passes
through the host's digestive system. While the cyst receives some protection from
degradation by the acidic environment of the stomach through the use of its outer wall,
it is likely to be destroyed at a pH lower than 5, allowing it to survive easier in the
stomachs of malnourished individuals who have less stomach acid. Once the cyst
reaches the small intestine, trophozoites are produced. The trophozoites then colonize
the large intestine, where they live in the lumen and feed on the intestinal flora. Some
trophozoites invade the wall of the colon using proteolytic enzymes and multiply,
causing ulcerative pathology in the colon wall, and some of them return to the lumen of
the large intestine and appendix, where they replicate by binary fission, during which
conjugation may occur. In the lumen, trophozoites may disintegrate or undergo
encystation. Encystation is triggered by dehydration of the intestinal contents and
usually occurs in the distal large intestine, but may also occur outside of the host in
faeces. The mature cyst forms are released into the environment when faeces are
passed, and can go on to infect a new host.
It can thrive in the gastrointestinal tract as long as there is a balance between the
protozoan and the host without causing dysenteric symptoms. Infection most likely
occurs in people with malnutrition due to the low stomach acidity or people with
compromised immune systems. In acute disease, explosive diarrhea may occur as
often as every twenty minutes. Perforation of the colon may also occur in acute
infections which can lead to life-threatening situations.
Extraintestinal infection is rare but potentially serious and typically occurs secondary to
intestinal infection. Peritonitis and liver abscesses have been noted following intestinal
perforation or rupture of fulminant colonic ulcers. Invasion of urogenital tract may be
caused by contamination from the anal region or through fistulae caused by severe
infection.
Clinical Presentation
Most cases are asymptomatic. Clinical manifestations, when present, may be acute or
chronic with abdominal symptoms. Complications of associated diarrhoea or dysentery
can occur in protracted infections. Symptoms may be severe or fatal in
debilitated/immunocompromised persons.

Life cycle of Balantidium coli
Treatment: Metronidazole, tetracycline and iodoquinol.

SPOROZOA
Sporozoa: Plasmodium species, Babesia microti, Toxoplasma gondii, Cryptosporidium
species
This group undergo complex sexual and asexual reproductive phases. Human parasites
among them include Plasmodium species, Cryptosporidium, Cyclospora and
Toxoplasma, which are all intracellular parasites.
Plasmodium species
Plasmodium is a member of the phylum Apicomplexa, a large group of parasitic
eukaryotes. Within Apicomplexa, Plasmodium is in the order Haemosporida and
family Plasmodiidae. Over 200 species of Plasmodium have been described.
Plasmodium are obligate parasites of vertebrates and insects. The life cycles
of Plasmodium species involve development in a blood-feeding insect host which then
injects parasites into a vertebrate host during a blood meal. Parasites grow within a
vertebrate body tissue (often the liver) before entering the bloodstream to infect red
blood cells. The ensuing destruction of host red blood cells can result in malaria. They
undergo the asexual replication process of merogony inside host red blood cells and
produce the crystalline pigment hemozoin as a byproduct of digesting
host hemoglobin. During this infection, some parasites are picked up by a blood-feeding
insect to continue the life cycle.
Species of Plasmodium are distributed globally wherever suitable hosts are found.
Insect hosts are most frequently mosquitoes of the genera Culex and Anopheles. Over
the course of the 20th century, many other species were discovered in various hosts
and classified, including five species that regularly infect humans: P. vivax, P.
falciparum, P. malariae, P. ovale, and P. knowlesi. P. falciparum is by far the most lethal
in humans, resulting in hundreds of thousands of deaths per year.
Although the parasite can also infect people through blood transfusion, this is very rare,
and Plasmodium cannot be spread from person to person. Some of subspecies
of Plasmodium are obligate intracellular parasites.
Epidemiology
Approximately 250 million people suffer from malaria, and between one and two million
die annually. The majority of deaths occur in African children and nearly all are caused
by P. falciparum. Malaria occurs throughout most of the tropical regions of the world. P.
falciparum predominates in Africa, New Guinea, and Haiti while P. vivax is more
common in Central America and the Indian subcontinent. The prevalence of these two
species is approximately equal in South America, and eastern Asia. P. malariae is found
in most endemic areas, especially throughout sub-Saharan Africa, but is much less
common than other species mentioned. P. ovale is relatively unusual outside of Africa
and where it is found, comprises