Week 5: Parasitology Part I Flashcards
learning objectives
For the parasitic organisms identify
- the geographic region of risk
- mode of transmission
- Life cycle
- Clinical symptoms
- Clinical complications of infection
- Laboratory diagnostic tests
- Appropriate treatment
- side effects of treatment
Case 1
Describe the distribution of Malaria
Question
Malaria is transmitted by the bite of the female Anopheles mosquito
Describe the mechanism of transmission of Malaria
- Malaria is transmitted by the bite of the female Anopheles Mosquito
- Sporozoites in the mosquito’s saliva are injected into the human bloodstream
- Vector-borne infection
Question
Merozoites
Describe the life-cycle of Malaria
Malaria is caused by?
Plasmodium species
Plasmodium characteristics
- Obligate intracellular protozoa
- Single-celled Eukaryotic
- The zygote is the only diploid stage in Plasmodium life-cycle
Tropism of Plasmodium
Blood protozoa with hepatic stage
Diploid stages of Plasmodium
The zygote is the only diploid stage in life-cycle
Definitive host of Plasmodium
Mosquito (sexual reproduction in the gut of the mosquito)
Intermediate host of Plasmodium
Human
(Asexual reproduction in liver and blood stages)
Plasmodium type and location of reproduction in definitive host
Mosquito (Sexual reproduction in the gut of the mosquito)
Plasmodium type and location of reproduction in intermediate host
Human (Asexual reproduction in liver and blood stages)
Factors associated with the pathogenicity of Plasmodium
4 listed
- Penetration of anatomic barrier via mosquito bite
- Avoidance of immune detection
- Antigenic variation, molecular mimicry, intracellular location, suppression of parasite-specific B & T-cell responses
- Replication in the host
- Endotoxin in P. falciparum
How do Plasmodium avoid immune detection
- Antigenic variation
- molecular mimicry
- Intracellular location
- suppression of parasite-specific B & T-cell responses
Question
D. Thick & thin peripheral blood smear
Thick and thin peripheral blood smear
Clinical symptoms of Malaria are caused by?
blood-stage parasites and the host immune response
Pathophysiology of Malaria infection
- RBC destruction
- Intravascular hemolysis -> severe microcytic, hypochromic anemia
- Cytokine release
- Schizont rupture -> macrophage stimulated to release TNF and IL-1 cytokines
- Sequestration of infected RBCs
- Adhere to capillary endothelial cells -> impair blood flow
- Splenomegaly
- Biochemical & electrolyte changes
- Hypoglycemia due to parasite glucose consumption, decreased hepatic gluconeogenesis, quinine causing pancreatic insulin release
- Metabolic acidosis from microvascular ischemia, parasite lactate production
- Hyponatremia
Pathophysiology of Malaria as a result of RBC destruction
Intravascular hemolysis -> severe microcytic hypochromic anemia
Pathophysiology of Malaria as a result of cytokine release
Schizont rupture -> macrophage stimulated to release TNF and IL-1 (cytokines)
Pathophysiology of Malaria as a result of sequestration of infected RBCs
- adhere to capillary endothelial cells -> impair blood flow
- Splenomegaly
Pathophysiology of Malaria as a result of biochemical & electrolyte changes
- Hypoglycemia due to parasite glucose consumption, decreased hepatic gluconeogenesis, quinine causing pancreatic insulin release
- Metabolic acidosis from microvascular ischemia, parasite lactate production
- Hyponatremia (SIADH)
What is SIADH
Syndrome of inappropriate antidiuretic hormone secretion (SIADH) is a condition in which the body makes too much antidiuretic hormone (ADH). … ADH is a substance produced naturally in an area of the brain called the hypothalamus. It is then released by the pituitary gland at the base of the brain.
Clinical findings & complications of Malaria
- General
- Periodic every 48 to 72 hours (q48 or g72 hr) paroxysmal fever, chills and rigors caused by immune reaction from lysis of RBCs
- Muscle aches, malaise, nausea, vomiting
- Cerebral Malaria
- Symptoms: impaired consciousness, delirium, seizures
- Capillary plugging due to accumulation of malarial pigment and P. falciparum schizont sequestration
- Mortality 15-25%
- Blackwater fever
- Intravascular hemolysis with rapid destruction of RBC infected with P. falciparum causing hemoglobinuria and acute renal failure
List of Plasmodium species
- P. falciparum
- P. malariae
- P. ovale
- P. vivax
P. falciparum region
Global
P. falciparum incubation period
short 7-10 days
P. falciparum RBC infected
All
P. falciparum latent liver phase
No
P. falciparum Fever
Malignant tertian
*Most severe presentation*
P. malariae region
- Africa
- Haiti
- DR
P. malariae incubation period
Long 18-40 days
P. malariae RBC infected
old
P. malariae latent liver phase
No
P. malariae fever
Quartan
P. ovale region
- Africa
- Asia
- SA
P. ovale incubation period
10-17 days
P. ovale RBC infected
Young
P. ovale latent liver phase
Yes
P. ovale fever
Benign tertian
P. vivax region
Global; NOT Africa
P. vivax incubation period
10-17 days
P. vivax RBC infected
- Young
- Duffy Ag
P. vivax latent liver phase
Yes
P. vivax fever
Benign tertian
Question
E. All of the above
because they all cause chronic low-grade anemia so there are less cells for the plasmodium to infect and reproduce in
Treatment of Malaria
- Blood schizonticide
- Tissue schizonticide
Blood schizonticides kill Plasmodium in what stage?
Trophozoite in RBC
Tissue schizonticide kill Plasmodium in what stage
Dormant hypnozoites in the liver (prevents relapse of OVALE and VIVAX)
Blood schizonticides
- Chloroquine
- Quinine
- Mefloquine
- Artemesins
- Atovaquone-proguanil
Tissue schizonticides
- Primaquine
Quinine indications
Treatment for severe malaria
Quinine MOA
- facilitates the aggregation of cytotoxic heme. Free cytotoxic heme accumulates in the parasites, causing their deaths.
- (toxic heme buildup and cell lysis)
Quinine side-effects
- arrhythmia
- Hemolysis in G6PD deficiency
- Cinchonism
Chloroquine indications
Many areas with resistant P. falcuparum and P. vivax
Blood schizonticides overview
Question
American trypanosomiasis
Describe the life-cycle of Trypanosoma cruzi
- Bugs bite humans and infect humans by defecating on humans and the wound is rubbed causing infection
- In humans, trypomastigotes lose flagellum and undulating membrane and become smaller oval intracellular amastigotes which multiply via binary fission and transform into trypomastigotes and burst out of the cell into the blood
- Triatomine bug takes a blood meal from infected human and epimastigotes use asexual reproduction and can infect another human via bite and defacation
Describe thick and thin smear
- thin smear - see the red cells and see the organism in its phase that is inside RBCs
- thick smear - to catch the gametocytes
- Get 3 thick and thin smears because this test is 100% operator dependent
Signs & symptoms of Acute Chagas Disease
- Chagoma at the inoculation site
- Fever, chills, malaise, myalgias, lymphadenopathy
- Rarely: arrhythmia, meningoencephalitis
- Romaña’s Sign
Question
D. Tsetse fly
Question
C. Leishmania braziliensis
Describe Leishmania life-cycle
- Sandfly takes a blood meal from infected human or animal and ingests infected macrophages with amastigotes
- amastigotes transform into promastigote stage in midgut of Sand fly and do asexual reproduction
- Sandfly takes a blood meal from human and promastigotes get phagocytosed by human macrophages
- Promastigotes transform into amastigotes inside macrophages
- Amastigotes multiply by binary fission invade other cells
Photos of Leishmaniasis
Question
D. Toxoplasma gondii
Describe the life-cycle of Toxoplasma gondii
- Organisms develop in the intestinal cells of cat & during extraintestinal cycle with passage to the tissue via the blood stream
- Organisms from intestinal cycle are passed in cat feces and mature into infective cysts within 3-4 days in the environment
- Oocysts (containing sporozoites) are ingested by humans (meat, cat feces) and produce acute and chronic infection
Question
A. Cat
