Abstract
Purpose: The purpose of this study is to model Cryptosporidiosis in laboratory animals. The
parasites were inoculated into animalsand thenmultiplied. The process of proliferation was
compared to controlCryptosporidiosis in humans.
Materials and Methods: Twenty-five laboratory mice (4-7 days of age) and twenty-five
laboratory rats (5 days of age) were assigned to the category I while the category II (control
group) consisted oftwenty-fiverats and twenty-five mice. The two categories were infected with
5×105 Cryptosporidium parvum oocysts originated from a calf by using a 24-gauge & 20-gauge
ball-point feeding needle. On 4-9 days of post inoculation the intestine, colon, and rectum
were removed. Cryptosporidium infection was determined by detecting oocysts in intestinal
homogenates by Staining and PCR method. Simple extraction and purification method was
used by ficoll gradient centrifugation. Also, twenty laboratory rats (4-6 weeks of age) were
intramuscularly injected with dexamethasone(Sigma, Chemical Co. UK) two times per week,
and the last injection was given with 5×105 Cryptosporidium parvum oocyst on the same day as
oral inoculation. The water was supplemented with tetracycline to avoiding secondary infections.
Results: Two to four million purified oocysts with a maximum of 10 million were routinely
obtained per mouse and rat. Also the day in which oocyst excretion is the highest was determined.
The number of oocyst per neonatal mouse was (11±2)×105 on 9-12 days of post infection while
similarly it was (10±1)×105 per neonatal rat.
Conclusion: The evaluation of the cryptosporidiosis in immunocompromised animal models
can help us to understand and control the Cryptosporidium infections.
parasites were inoculated into animalsand thenmultiplied. The process of proliferation was
compared to controlCryptosporidiosis in humans.
Materials and Methods: Twenty-five laboratory mice (4-7 days of age) and twenty-five
laboratory rats (5 days of age) were assigned to the category I while the category II (control
group) consisted oftwenty-fiverats and twenty-five mice. The two categories were infected with
5×105 Cryptosporidium parvum oocysts originated from a calf by using a 24-gauge & 20-gauge
ball-point feeding needle. On 4-9 days of post inoculation the intestine, colon, and rectum
were removed. Cryptosporidium infection was determined by detecting oocysts in intestinal
homogenates by Staining and PCR method. Simple extraction and purification method was
used by ficoll gradient centrifugation. Also, twenty laboratory rats (4-6 weeks of age) were
intramuscularly injected with dexamethasone(Sigma, Chemical Co. UK) two times per week,
and the last injection was given with 5×105 Cryptosporidium parvum oocyst on the same day as
oral inoculation. The water was supplemented with tetracycline to avoiding secondary infections.
Results: Two to four million purified oocysts with a maximum of 10 million were routinely
obtained per mouse and rat. Also the day in which oocyst excretion is the highest was determined.
The number of oocyst per neonatal mouse was (11±2)×105 on 9-12 days of post infection while
similarly it was (10±1)×105 per neonatal rat.
Conclusion: The evaluation of the cryptosporidiosis in immunocompromised animal models
can help us to understand and control the Cryptosporidium infections.
Keywords
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© 2016, Annals of Military and Health Sciences Research. This open-access article is available under the Creative Commons Attribution-NonCommercial 4.0 (CC BY-NC 4.0) International License (https://creativecommons.org/licenses/by-nc/4.0/), which allows for the copying and redistribution of the material only for noncommercial purposes, provided that the original work is properly cited.