Pathogens Causing CVD: Trypanosomes PDF

Summary

This document presents information about pathogens causing cardiovascular diseases, specifically focusing on trypanosomes, covering different types, symptoms, and spread. It outlines details of the medically important haemoflagellates and their impact on various regions.

Full Transcript

Pathogens Causing CVD:
C. Trypanosomes:
❑The medically important haemoflagellates are two
genera:
1. Genus: Leishmania
2. Genus: Trypanosoma
❑Trypanosoma:
A. African trypanosomes:
i. Trypanosoma brucei gambiense.
ii. Trypanosoma brucei rhodesiense
B. American trypanosome:
i. Trypanosoma cruzi
 Pathogens Causing CVD:
C. Trypanosomes:
❑Haemoflagellates:
▪ They are the flagellated protozoa that are found in
peripheral blood circulation.
▪ Infect blood and tissue.
▪ They complete their life cycle in two hosts, i.e. vertebrate
host and insect vector.
 Haemoflagellates:
❑ African trypanosomiasis:
▪ Disease: Sleeping sickness,
▪ Caused by Trypanosoma brucei and
▪ Transmitted by tsetse flies.
❑South American trypanosomiasis: َّ ‫ذُبَابَةُّتْسيُّتْسيُّأوُّال‬
‫شذاةُّأوُّالالَّسنَة‬
▪ Disease: Chagas disease, ‫مرض شاغاس‬
▪ Chagas disease: also known as American trypanosomiasis is
a tropical parasitic disease caused by the Trypanosoma
cruzi. It is spread mostly by reduviid insects ‫الحشرات المخففة‬
Family: Triatominae, or "kissing bugs". ‫ البَقُّ ال ُمقَبُّل‬/‫ الفسافس‬/‫البق‬

‫ُّالبَقُّال ُمقَبل‬/‫ُّالفسافس‬/‫البق‬
 Pathogenesis and Clinical Symptoms:
❑The symptoms of hemoflagellate infections:
1. Range from minor symptoms , such as irritation at the
infection site with small red papule at the infection site,
& intense itching,
2. To Serious Form (comatose state and death).
▪ Secondary bacterial infections, fever, and diarrhea, to
kidney involvement, mental retardation, a comatose state,
and death.
❑ In some cases, the initial skin lesions spontaneously heal,
whereas in others they may remain dormant for months or
even years.
 Trypanosoma:
A. African trypanosomes:
1. Trypanosoma brucei gambiense
2. Trypanosoma brucei rhodesiense
❑Trypanosoma gambiense & Trypanosoma rhodesiense:
▪ They are also known as Trypanosoma brucei gambiense
and Trypanosoma brucei rhodesiense.
▪ Both Causing African Trypanosomiasis, Sleeping
Sickness.
▪ T. b. rhodesiense is found in Eastern and central
Africa.
▪ T. b. rhodesiense is a much more virulent organism
than T. b. gambiense.
▪ T. b. rhodesiense Cause: East African (Rhodesian)
Sleeping Sickness.
▪ T. b. gambiense is found in West & Central Africa.
 Trypanosoma:
❑Important Properties:
1. The morphology and life cycle of the two species are
similar.
2. The vector for both African trypanosomes is the tsetse
fly.
3. Humans are the reservoir for T. gambiense, whereas T.
rhodesiense has reservoirs in both domestic animals
(especially Sheep & Cattle) and wild animals (e.g.,
antelopes). ‫الظبي‬
4. The 3-week life cycle in the tsetse fly begins with
ingestion of Blood Trypomastigotes in a blood meal
from the reservoir host.
i. Bloodstream Trypomastigotes multiply in the insect
gut & transform into Procyclic Trypomastigotes.
 Trypanosoma:
ii. Procyclic Trypomastigotes then migrate to the salivary
glands, where they transform into Epimastigote.
iii. Epimastigote multiply further in salivary glands, and
then form Metacyclic Trypomastigotes, which are
transmitted by the tsetse fly bite.
5. The organisms in the saliva are injected into the skin, where
they enter the bloodstream, differentiate into blood-form
trypomastigotes, and multiply, thereby completing the cycle.
❖Note that these species are rarely found as Amastigotes in
tissue, in contrast to T. cruzi and Leishmania species, in
which Amastigotes are commonly found.
 Trypanosoma:
6. These trypanosomes exhibit remarkable antigenic
variation of their surface glycoproteins, with
hundreds of antigenic types found.
i. One antigenic type will coat the surface of the parasites
for approximately 10 days, followed by other types in
sequence in the new progeny.
ii. This variation is due to sequential movement of the
Glycoprotein genes to a preferential location on the
chromosome, where only that specific gene is
transcribed into mRNA.
iii. These antigenic variations allow the organism to
continually evade the host immune response.
 Trypanosoma:
1. T. brucei gambiense:
▪ Causes slow onset chronic trypanosomiasis in humans.
▪ Most common in central and western Africa, where
humans are thought to be the primary reservoir.
2. T. brucei rhodesiense:
▪ Causes fast onset acute trypanosomiasis in humans.
▪ Most common in southern, central, and eastern Africa,
where both domestic animals (especially Sheep & Cattle)
and wild animals (e.g., antelopes).
 Trypanosoma:
❑Life Cycle of T. rhodesiense & T. gambiense
are Same:
▪ The only difference in the life cycles of T. b. rhodesiense and
T. b. gambiense are the species of tsetse fly vector (Genus:
Glossina).
1. The two species of tsetse flies responsible for the
transmission of T. b. gambiense are:
i. Glossina palpalis and
ii. Glossina tachinoides.
▪ There are no known animal reservoir hosts.
2. The two primary species of tsetse fly vectors responsible for
transmitting T. b. rhodesiense are:
i. Glossina morsitans and
ii. Glossina pallidipes.
 Trypanosoma:
❑Pathogenesis & Epidemiology:
1. The trypomastigotes spread from the skin through the
blood to the lymph nodes and the brain.
2. The typical somnolence (sleeping sickness) progresses to
coma as a result of a demyelinating encephalitis.
3. In the acute form, a cyclical fever spike (approximately
every 2 weeks) occurs that is related to antigenic
variation.
▪ As antibody-mediated agglutination and lysis of the
trypomastigotes occur, the fever subsides.
▪ However, a few antigenic variants survive, multiply, and
cause a new fever spike.
▪ This cycle repeats itself over a long period.
▪ The lytic antibody is directed against the surface
glycoprotein.
 Trypanosoma:
❑Pathogenesis & Epidemiology:
4. The disease is endemic in sub-Saharan Africa, the
natural habitat of the tsetse fly.
▪ Both sexes of fly take blood meals and can transmit the
disease.
▪ T. b. gambiense has also been shown to be acquired
through blood transfusion, organ transplantation, and
congenital transmission (from pregnant mother to fetus).
▪ The fly is infectious throughout its 2- to 3-month lifetime.
o T. gambiense is the species that causes the disease along
water courses in west & Central Africa, whereas
o T. rhodesiense is found in the arid regions of east & Central
Africa.
o Both species are found in central Africa.
 Trypanosoma:
❑Clinical Findings:
▪Both species cause sleeping sickness, the progress
of the disease differs.
▪ T. gambiense–induced disease runs a low-grade
chronic course over a few years, whereas
▪ T. rhodesiense causes a more acute, rapidly
progressive disease that, if untreated, is usually
fatal within several months.
1. The initial lesion is an indurated skin ulcer ("trypanosomal
chancre") at the site of the fly bite.
2. After the organisms enter the blood, intermittent weekly
fever and lymphadenopathy develop.
 Trypanosoma:
❑Clinical Findings:
3. Enlargement of the posterior cervical lymph nodes
(Winterbottom's sign) is commonly seen.
4. The encephalitis is characterized initially by headache,
insomnia, and mood changes, followed by muscle tremors,
‫كالم غير واضح‬
slurred speech, and apathy that progress to somnolence and
coma.
5. Untreated disease is usually fatal as a result of pneumonia.
 Trypanosoma:
❑Laboratory Diagnosis:
1. During the early stages,
▪ Microscopic examination of the blood (either wet films or
thick or thin smears) reveals trypomastigotes.
▪ An aspirate of the chancre or enlarged lymph node can
also demonstrate the parasites.
▪ The presence of trypanosomes in the spinal fluid, coupled
with an elevated protein level, pleocytosis, and elevated
IgM; indicates that the patient has entered the late
encephalitic stage.
▪ Serologic tests, especially the ELISA for IgM antibody, can
be helpful.
 Trypanosoma:
❑Laboratory Diagnosis:
❑Specimens:
▪ Blood, lymph node aspirations, and CSF are the
specimens of choice for diagnosing T. b. gambiense.
1. Giemsa-stained slides of blood and lymph node
aspirations from infected patients reveal the typical
trypomastigote morphologic forms.
2. CSF:
i. Several tests may be performed on CSF—
microscopic examination of the sediment for
trypomastigotes,
 Trypanosoma:
❑Laboratory Diagnosis:
2. CSF:
ii. Detection of the presence of immunoglobulin M
(IgM), and
iii. Detection of the presence of proteins.
iv. Infected patients typically have high levels of both
IgM and proteins in their CSF.
1. In addition, serum IgM testing may be indicated.
2. The presence of IgM in serum and/or CSF is
generally considered diagnostic.
 Trypanosoma:
❑Treatment:
1. Treatment must be initiated before the development
of encephalitis, because Suramin, the most effective
drug, does not pass the blood-brain barrier well.
▪ Suramin will effect a cure if given early.
2. Pentamidine is an alternative drug.
3. If central nervous system symptoms are present,
suramin (to clear the parasitemia) followed by
Melarsoprol should be given.
 Trypanosoma:
❑Prevention:
▪ The most important preventive measure is protection
against the fly bite, using:
i. Netting and
ii. Protective clothing.
iii. Clearing the forest around villages.
iv. Using insecticides are helpful measures.
v. No vaccine is available.
❑Trypanosoma brucei—Trypomastigotes: Arrow
points to a trypomastigote (the flagellated form) in the
blood.
 American Trypanosoma:
❑ Trypanosoma cruzi
❑Disease: Chagas’ disease
▪ Trypanosoma cruzi, the causative agent of Chagas’ disease,
was described in 1909 by a young medical student in Brazil
named Carlos Chagas.
❑ Epidemiology:
▪ Trypanosoma cruzi is found in southern portions of
the United States, Mexico, and Central and South
America. Commonly referred to as Chagas’ disease or
American trypanosomiasis,
▪ the disease course for this illness often presents itself with
cardiac and gastrointestinal distress.
❑Trypanosoma cruzi trypomastigote exhibiting a characteristic
full body length undulating membrane (arrow).
❑Trypanosoma cruzi C-
shaped Trypomastigoten
in a blood smear.
❑Life Cycle of Trypanosoma cruzi:
❑Mode of Transmission of T. cruzi:
1. Transferred to a human host when a reduviid bug vector
defecates infective trypomastigotes near the site of its blood
meal.
2. The presence of the bite produces an itching sensation in
the host.
3. As the host scratches the bite area, the trypomastigotes gain
entry into the host by rubbed into the bite wound.
4. Additional routes of transferring T. cruzi include:
i. Blood transfusions,
ii. Sexual intercourse,
iii. Transplacental transmission, and
iv. Entry through the mucous membranes when the bug
bite is near the eye or mouth.
 American Trypanosoma:
❑Life Cycle of Trypanosoma cruzi:
5. Following entry into the host, the trypomastigotes
invade surrounding cells, where they transform into
Amastigotes.
6. The amastigotes proceed to multiply, destroy the
host cells, and then convert back into
trypomastigotes.
▪ The resulting trypomastigotes migrate through the blood,
penetrate additional cells in the body, and transform back
into amastigotes, and the replication and the cycle repeats.
 American Trypanosoma:
❑Life Cycle of Trypanosoma cruzi:
7. A number of areas in the body may become
infected, including the heart muscle, liver, and brain.
i. The T. cruzi trypomastigotes are transmitted back to the
reduviid bug when it feeds, via a blood meal, on an
infected human.
ii. On ingestion, the trypomastigotes transform into
Epimastigote in the midgut.
iii. Multiplication of the epimastigotes produces thousands
of additional parasites that convert back into
trypomastigotes when they reach the hindgut.
iv. These trypomastigotes are then passed with the feces
when the bug defecates near the site of its next blood
meal, and thus the cycle begins again.
❑ Epimastigotes:
▪ May rarely be seen
in the circulating
blood;
▪ however, this form is
primarily found only
in the arthropod
vector.

Epimastigote:
Parameter Description
Size 9-15 μm long
Shape Long and slightly wider than promastigote form
Nucleus One, located in posterior end
Other features Kinetoplast located anterior to the nucleus.
Undulating membrane, extending (½) body
length Free flagellum, extending from anterior
end
 Trypomastigote:
Parameter Description
Size 12-35 μm long by 2-4 μm wide
Shape C, S or U shape often seen in stained blood films.
Appearance Long and slender
Nucleus One, located anterior to the Kinetoplast.
Other features Kinetoplast located in the posterior
End. Undulating membrane, extending entire body
length Free flagellum, extending from anterior end
when present

❑Trypomastigotes:
❑Found in blood
specimen.
▪ Trypanosoma cruzi ▪ Trypanosoma cruzi C-
trypomastigote exhibiting a shaped trypomastigote in
characteristic full body length a blood smear.
undulating membrane
(arrow).
Trypomastigote:
anterior

Undulating
membrane

posterior
 American Trypanosoma:
❑Clinical Symptoms of Trypanosoma cruzi:
A. Chagas’ Disease:
▪ Chagas’ disease may be asymptomatic, chronic, or acute in
nature.
B. Chagoma:
▪ The most common initial symptom is the development of
an erythematous nodule, at the site of infection produced
by the proliferation of the T. cruzi organisms.
▪ Occurs any where in the body, but it is most frequently
located on the face.
▪ Edema as well as a rash around the eyes and face.
▪ The painful chagoma may last 2 to 3 months before
subsiding.
C. Patients who contract T. cruzi through the ocular
mucosa develop a characteristic conjunctivitis and
unilateral edema of the eyelids, a condition known
as Romana's sign.
 American Trypanosoma:
❑Clinical Symptoms of Trypanosoma cruzi:
❑Chagas’ Disease:
▪ Patients suffering from acute Chagas’ disease typically experience fever,
chills, fatigue, myalgia, and malaise.
❑An attack of acute infection may result in one of the following
scenarios:
1. Recovery;
2. Transition to the chronic stage of disease; or
3. Death, which usually occurs a few weeks after the attack.
❑Chagas’ disease is most commonly seen in children younger than
5 years.
▪ These patients characteristically present with symptoms of CNS.
❑After experiencing an initial acute attack, adults and children older
than 5 years usually develop a milder chronic or subacute form of
the disease.
 Lab. Diagnosis of T. cruzi
❑Specimens:
▪Blood Film, L/N biopsy, Blood for Culture,
Serum.
1. Giemsa-stained blood slides are the specimen of
choice for detection of the typical T. cruzi
trypomastigotes.
2. Epimastigotes may rarely be seen in the circulating
blood; however, this form is primarily found only
in the arthropod vector.
3. Lymph node biopsy Giemsa-stained slides, as well
as blood culture, may reveal the typical
amastigotes.
 Lab. Diagnosis of T. cruzi
4. A number of serologic tests, including:
i. Complement fixation (CF),
ii. DAT, and
iii. Indirect immunofluorescence (IIF), are
also available for diagnostic purposes.
5. The polymerase chain reaction (PCR) and
6. ELISA testing methods are also available for
diagnosing infections with T. cruzi;
▪ ELISA is used in blood donor screening to help ensure
the safety of transfusable blood and transplantable organs.
 Treatment of T. cruzi
1. The treatment of choice for infections
with T. cruzi is Nifurtimox (Lampit).
2. Other medications include:
▪Benznidazole, Allopurinol, and ketoconazole
(the antifungal agent).
 Prevention of T. cruzi
1. The eradication of reduviid bug nests and
the construction of homes without open.
2. DDT has proved to be useful, not only to
control the reduviid population but also to
decrease the incidence of malaria.
3. Educational programs designed to inform
people, especially in endemic areas, of the
disease, its transmission, and possible
reservoir hosts may also prove to be helpful
in the fight against T. cruzi transmission.
4. In addition, the prospects for developing a
vaccine appear to be promising.