Objectives
At the end of this sub-unit, students will be able to:
Explain the classification and characteristics of blood and tissue flagellates
Discuss the epidemiology, life cycle, and clinical aspects of Leishmania parasites
Discuss the epidemiology, life cycle, and clinical aspects of Trypanosoma species
TEST BANK For Lewis's Medical Surgical Nursing in Canada, 4th Edition by Jane...
3.3. Blood and tissue flagelates.ppt
1. Blood and Tissue flagellates
Objectives
At the end of this sub-unit, students will be able to:
1. Explain the classification and characteristics of blood and tissue
flagellates
2. Discuss the epidemiology, life cycle and clinical aspects of
Leishmania parasites
3. Discuss the epidemiology, life cycle and clinical aspects of
trypanosoma species
By: Asmamaw Tesfaye
2. Outline
Classification of blood and tissue flagellates
Characteristics of blood & tissue flagellates
Leishmania (different forms)
Trypanosoma brucie complex
Trypanosoma cruzi
By: Asmamaw Tesfaye
3. Classification
kingdom -------- protista
subkingdom -----protozoa
phylum -----------sarcomastigophora
subphylum -------mastigophora
class ---------------zoomastigophora
order --------------kinetoplastida
family -------------trypanosomatidae
genus --------------Leishmania, trypanosoma
By: Asmamaw Tesfaye
4. General Characteristics
Reproduce by longitudinal binary fission.
Use biological insect vectors as intermediate hosts & human
as definitive host.
The species are morphologically indistinguishable, but they
can be differentiated on the basis of their:
Clinical features
Geographical distribution
Vector species
Reservoir hosts
Immunological and molecular tests
By: Asmamaw Tesfaye
5. Developmental forms
The different developmental forms are differentiated on the basis of
Presence or absence of free flagellum
Presence or absence of undulating membrane
Position of the kinetoplast relative to the nucleus
1. Amastigote(Leishmanial form)
Rounded body, large nucleus and
eccentric kinetoplast visible
No free flagellum
No undulating membrane
The only intracellular forms of all
leishmania species and Trypanosoma
cruzi
By: Asmamaw Tesfaye
6. Developmental forms…
• Elongated body, central nucleus, anterior kinetoplast
• Single anterior flagellum arises from kinetoplast
• Found in the invertebrate host, and in culture media
of all Leishmania species
By: Asmamaw Tesfaye
7. Developmental forms…
3. Epimastigote (crithidial forms)
• Elongated body, single free flagellum, single nucleus
• Has undulating membrane
• Kinetoplast is just anterior to the nucleus
• Found in the invertebrate host and in culture media of
Trypanosome species
By: G. A.
8. Developmental forms…
4. Trypomastigote (Trypanosomal forms)
• Pleomorphic, it can be seen as “U” or “C” shaped
• Central nucleus, posterior kinetoplast
• Single Flagellum arises posteriorly
• Has undulating membrane
• Found in the peripheral blood of vertebrates and
• is the diagnostic stage of Trypanosome species
By: G. A.
9. Developmental forms…
5. Metacyclic Trypomastigote
• Morphologically similar to trypomastigote stage but it is short
and stumpy
• Final developmental stage in the gut of the insect vectors
• Infective stage of Trypanosome species
By: Asmamaw Tesfaye
10. Leishmania species
Causative agent of leishmaniasis
Obligate intracellular to mononuclear phagocytes
Human infection is caused by > 20 of 30 species that infect
mammals.
L. donovani complex
L. donovani
L. infantum
L. chagasi
L. chinensis
L. archibaldi
By: Asmamaw Tesfaye
11. …
Cutaneous leishmaniasis(CL)
Visceral leishmaniasis(VL)
L. donovani
L. infantum
L. Chagasi
L. tropica
L. major
L. aethiopica
L. panamensis
L. guyanensis
L. peruviana
L. mexicana
Mucocutaneous leishmaniasis(MCL)
L. panamensis
L. guyanensis
L. Brazilliensis
L. aethiopica
Diffuse cutaneous leishmaniasis (DCL)
• L. amazonensis
• L. aethiopica
Clinical classification
By: Asmamaw Tesfaye
12. Epidemiology
350 million people are at risk in 98 countries around the world
Annual incidence estimated to be 0.9 – 1.6 million (all forms)
Incidence of VL: 200,000-400,000 cases /year
Mortality due to VL: 20,000 - 40,000 /year
An estimated 12 million cases world wide
CL form representing 50 to 75% of all new cases
Most of the affected countries are in tropics and sub tropics
90% of all VL cases occur in Bangladesh, Brazil, India, Ethiopia, Sudan
and south Sudan.
90% of all MCL cases occurs in Bolivia, Brazil and Peru
90% of all CL cases occur in Afghanistan, Brazil, Iran, Peru, Saudi Arabia
Algeria, pakistan and Syria
By: Asmamaw Tesfaye
14. Global Status
L. donovani
L. infantum
L. tropica
L. major
L. aethiopica
old world:
Asia, Africa, Europe
new world:
south and central America
L. infantum
( L. chagasi )
L.mexicana
L.brazilliensis
L. peruriana
L.panamensis
L.guyanensis
L.amzonensis
By: Asmamaw Tesfaye
15. The incidence of leishmaniasis is increasing, mainly because of:
Man-made environmental changes
Poverty and malnutrition
Climate change
Movement of susceptible populations into endemic areas
By: Asmamaw Tesfaye
16. Distribution in Ethiopia
Visceral leishmaniasis (VL): L. donovani
Occurs mainly in arid and semiarid lowlands below 1500 m
altitude. Important endemic foci are:
Northwest Ethiopia (2/3 of national burden)
Metema, Armacho, Quara, Humera and T/Adiabo -low lands
Libokemkem/ Fogera districts of Amhara Regional state -high
lands( new foci 2005)
South and southwest Ethiopia
Dawa, Genale, Konso/Segen, Woito, and Omo River Valleys
Ethio–Kenyan Boarder, Guji and Borena zones
Ethio - Sudanese Boarder
Northeastern Ethiopia
Awash Valley areas
Ethio-Djibout Boarder–cases reported
Eastern Ethiopia – Somali region
By: Asmamaw Tesfaye
17. Distribution in Ethiopia….
Cutaneous leishmaniasis: L. aethiopica, L.major, L. tropica
Endemic at altitudes 1400 - 2700 m in most administrative regions
Prevalence rates of 5.5 – 40% were reported from villages in
Shewa , Wello and G.Gofa with the highest rate in Ocholo village
in G. Gofa
Rock (Procavia habessinica) & tree (Heterhyrax brucei ) hyraxes
serving as reservoir host for L. aethiopica
By: Asmamaw Tesfaye
18. Transmission and life cycle
Common mode of transmission: Bite of sand fly
Genera Phlebotomus vs Lutzomyia
Uncommon modes of transmission:
Congenital transmission
Blood transfusion
Sharp materials
Breeding sites for the sand flies
Balanite Trees
Acacia Forests
Black cotton soil
Termite Hills
Favorable Environmental conditions
Altitude below 1500 meters (low land)
High level humidity (70-80% Relative
Humidity)
High T: 25-32o C
For VL transmitting vectors
By: Asmamaw Tesfaye
19. 19
BALANITE TREE
ACACIA TREE
P.orientalis in the North
is associated with black
cotton soil, red Accacia
and Balanite trees
By: Asmamaw Tesfaye
20. P.orientalis in the North
is associated with black
cotton soil, red Accacia
and Balanite trees
Phlebotomus martini/ celiae
in the South are usually
associated with termite hills.
By: Asmamaw Tesfaye
24. Life cycle….
Female sandflies inject promastigote stage during blood meals
Promastigotes are phagocytized by macrophages & transform into
intracellular amastigote form
Amastigotes multiply by binary fission, rapture from macrophages ,
and infect new cells
• In VL the amastigotes are carried through blood circulation , then invade
and multiply in the macrophages of spleen, liver, bone marrow, lymph glands
• In CL , MCL – the amasigote multiply in skin macrophages (histocytes)
Sand flies become infected during blood meals when they ingest
macrophages infected with amastigotes
The host cell break down and release amasigotes which are then
transformed to promastigotes
Multiply, fill the lumen of the gut and migrate to the proboscis
By: Asmamaw Tesfaye
25. Pathogenesis
Entrance into the host and establishment of infection by leishmanias
is enhanced by saliva from the vector
Two substances are involved
maxadilin, or maximum dilation molecule: keeps the capillary
bed open at the site of feeding for about 48 hours
SIP or salivary immunosuppressive protein : restrains the
immune system’s early efforts to eliminate the parasites
Infective promastigotes entering the blood of the vertebrate are
covered by two key molecules: the protein gp 63 and
lipophosphoglycan (LPG). Both mediate the uptake of
promastigotes by macrophages
The promastigotes are engulfed & form phagosome
By: Asmamaw Tesfaye
26. Pathogenesis…
Phagosome fuse with the lysosome to form a phagolysosome
As the promastigotes transform into amastigotes, which
produce compounds that counter lysosomal enzymes
The gp 63 molecule inactivates proteolytic enzymes
LPG protects against other enzymes
Leishmanial organisms are able to survive the highly acidic
environment of lysosomes by regulating their internal PH.
By: Asmamaw Tesfaye
