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Toxoplasmosis

[Toxoplasma gondii]

Causal Agents

Toxoplasma gondii is a protozoan parasite that infects most species of warm-blooded animals, including humans, and causes the disease toxoplasmosis.

Life Cycle

Toxoplasma_LifeCycle_BAM1.gif

The only known definitive hosts for Toxoplasma gondii are members of family Felidae (domestic cats and their relatives). Unsporulated oocysts are shed in the cat’s feces  . Although oocysts are usually only shed for 1–3 weeks, large numbers may be shed. Oocysts take 1–5 days to sporulate in the environment and become infective. Intermediate hosts in nature (including birds and rodents) become infected after ingesting soil, water or plant material contaminated with oocysts  . Oocysts transform into tachyzoites shortly after ingestion. These tachyzoites localize in neural and muscle tissue and develop into tissue cyst bradyzoites  . Cats become infected after consuming intermediate hosts harboring tissue cysts  . Cats may also become infected directly by ingestion of sporulated oocysts. Animals bred for human consumption and wild game may also become infected with tissue cysts after ingestion of sporulated oocysts in the environment  . Humans can become infected by any of several routes:

  • Eating undercooked meat of animals harboring tissue cysts  .
  • Consuming food or water contaminated with cat feces or by contaminated environmental samples (such as fecal-contaminated soil or changing the litter box of a pet cat)  .
  • Blood transfusion or organ transplantation  .
  • Transplacentally from mother to fetus  .

In the human host, the parasites form tissue cysts, most commonly in skeletal muscle, myocardium, brain, and eyes; these cysts may remain throughout the life of the host. Diagnosis is usually achieved by serology, although tissue cysts may be observed in stained biopsy specimens  . Diagnosis of congenital infections can be achieved by detecting T. gondii DNA in amniotic fluid using molecular methods such as PCR  .

Geographic Distribution

Serologic prevalence data indicate that toxoplasmosis is one of the most common human infections throughout the world. A high prevalence of infection in France has been related to a preference for eating raw or undercooked meat, while a high prevalence in Central America has been related to the frequency of stray cats in a climate favoring survival of oocysts and soil exposure. The overall seroprevalence in the United States among adolescents and adults, as determined with specimens collected by the third National Health and Nutrition Examination Survey (NHANES III) between 1988 and 1994, was found to be 22.5%, with a seroprevalence among women of childbearing age (15 to 44 years) of 15%. In a more recent evaluation using data from NHANES 2009–2010, the overall age-adjusted T. gondii antibody seroprevalence among persons > 6 years of age was 12.4%, and among women 15–44 years of age was 9.1%.

Clinical Presentation

Acquired infection with Toxoplasma in immunocompetent persons is generally an asymptomatic infection. However, 10% to 20% of patients with acute infection may develop cervical lymphadenopathy and/or a flu-like illness. The clinical course is usually benign and self-limited; symptoms usually resolve within a few weeks to months. In rare cases ocular infection with visual loss can occur. Immunodeficient patients often have central nervous system (CNS) disease but may have retinochoroiditis, pneumonitis, or other systemic disease. In patients with AIDS, toxoplasmic encephalitis is the most common cause of intracerebral mass lesions and is thought to usually be caused by reactivation of chronic infection. Toxoplasmosis in patients being treated with immunosuppressive drugs may be due to either newly acquired or reactivated latent infection.

Congenital toxoplasmosis results from an acute primary infection acquired by the mother during pregnancy. The incidence and severity of congenital toxoplasmosis vary with the trimester during which infection was acquired. Because treatment of the mother may reduce the incidence of congenital infection and reduce sequelae in the infant, prompt and accurate diagnosis is important. Many infants with subclinical infection at birth will subsequently develop signs or symptoms of congenital toxoplasmosis. Ocular Toxoplasma infection, an important cause of retinochoroiditis in the United States, can be the result of congenital infection, or infection after birth. In congenital infection, patients are often asymptomatic until the second or third decade of life, when lesions develop in the eye.

Toxoplasma gondii tachyzoites.

 

Tachyzoites (trophozoites) of Toxoplasma gondii are approximately 4-8 µm long by 2-3 µm wide, with a tapered anterior end, a blunt posterior end and a large nucleus. They may be found in various sites throughout the body of the host.
Figure A: Toxoplasma gondii tachyzoites, stained with Giemsa, from a smear of peritoneal fluid obtained from a laboratory-inoculated mouse.
Toxoplasma gondii cyst in brain tissue.

 

Cysts of Toxoplasma gondii usually range in size from 5-50 µ in diameter. Cysts are usually spherical in the brain but more elongated in cardiac and skeletal muscles. They may be found in various sites throughout the body of the host, but are most common in the brain and skeletal and cardiac muscles.
Figure A: Toxoplasma gondii cyst in brain tissue stained with hematoxylin and eosin.
Figure B: Toxoplasma gondii cyst stained with hematoxylin and eosin.
Toxoplasma gondii cyst, unstained.

 

Cysts of Toxoplasma gondii usually range in size from 5-50 µm in diameter. Cysts are usually spherical in the brain but more elongated in cardiac and skeletal muscles. They may be found in various sites throughout the body of the host, but are most common in the brain and skeletal and cardiac muscles.
Figure A: Unstained cyst of T. gondii.
Toxoplasma gondii sporulated oocyst.

 

Oocysts of Toxoplasma gondii are shed only in the feces of domestic and wild felids, the definitive hosts. Sexual reproduction takes place in the intestinal epithelium of the cat host and cysts are shed unsporulated in the feces. In the environment, cysts take 48-72 hours to sporulate and become infective. Mature oocysts measure 10-12 µm in diameter and contain two sporocysts. Human infection may occur either from ingestion of sporulated oocysts, or ingestion of meat infected with trophozoites.
Figure A: Toxoplasma gondii sporulated oocyst in an unstained wet mount.
Figure B: Toxoplasma gondii sporulated oocyst in an unstained wet mount, viewed under differential interference contrast (DIC) microscopy.
Toxoplasma gondii unsporulated oocysts.

 

Oocysts of Toxoplasma gondii are shed only in the feces of domestic and wild felids, the definitive hosts. Sexual reproduction takes place in the intestinal epithelium of the cat host and cysts are shed unsporulated in the feces. In the environment, cysts take 48-72 hours to sporulate and become infective. Mature oocysts measure 10-12 µm in diameter and contain two sporocysts. Human infection may occur either from ingestion of sporulated oocysts, or ingestion of meat infected with trophozoites.
Figure A: Unsporulated T. gondii oocyst in an unstained wet mount.
Figure B: Unsporulated oocyst of T. gondii in an unstained wet mount, viewed with differential interference contrast (DIC) microscopy.
Figure C: T. gondii oocysts in a fecal floatation.
Figure D: Higher magnification of Figure C.
Ocular toxoplasmosis: Chorioretinitis.

 

Ocular toxoplasmosis.
Figure A: Severe, active retinochoroiditis.
Figure B: Peripheral retinochoroiditis.
Figure C: Central, healed retinochoroiditis.

Laboratory Diagnosis

The diagnosis of toxoplasmosis may be documented by:

  • Observation of parasites in patient specimens, such as bronchoalveolar lavage material from immunocompromised patients, or lymph node biopsy.
  • Isolation of parasites from blood or other body fluids, by intraperitoneal inoculation into mice or tissue culture. The mice should be tested for the presence of Toxoplasma organisms in the peritoneal fluid 6 to 10 days post inoculation; if no organisms are found, serology can be performed on the animals 4 to 6 weeks post inoculation.
  • Detection of parasite genetic material by PCR, especially in detecting congenital infections in utero.
  • Serologic testing is the routine method of diagnosis.

 

Antibody Detection

The detection of Toxoplasma-specific antibodies is the primary diagnostic method to determine infection with Toxoplasma. Toxoplasma antibody detection tests are performed by a large number of laboratories with commercially available kits.

An algorithm for the immunodiagnosis of toxoplasmosis for individuals greater than one year of age is shown table below. The IFA and EIA tests for IgG and IgM antibodies are the tests most commonly used today. Persons should be initially tested for the presence of Toxoplasma-specific IgG antibodies to determine their immune status. A positive IgG titer indicates infection with the organism at some time. If more precise knowledge of the time of infection is necessary, then an IgG positive person should have an IgM test performed by a procedure with minimal nonspecific reactions, such as IgM-capture EIA. A negative IgM test essentially excludes recent infection, but a positive IgM test is difficult to interpret because Toxoplasma-specific IgM antibodies may be detected by EIA for as long as 18 months after acute acquired infection.

A major problem with Toxoplasma-specific IgM testing is lack of specificity.  Two situations occur frequently: i) persons with a positive IgM but negative IgG, and ii) individuals with positive IgG and IgM results.  In the first situation, a positive IgM result with a negative IgG result in the same specimen should be viewed with great suspicion; the patient’s blood should be redrawn two weeks after the first and tested together with the first specimen. If the first specimen was drawn very early after infection, the patient should have highly positive IgG and IgM antibodies in the second sample. If the IgG is negative and the IgM is positive in both specimens, the IgM result should be considered to be a false positive and the patient should be considered to be not infected. In the second situation, a second specimen should be drawn and both specimens submitted together to a reference lab which employs a different IgM testing system for confirmation.

If the patient is pregnant, and IgG/IgM positive, an IgG avidity test should be performed. A high avidity result in the first 12 to 16 weeks of pregnancy (time dependent upon the commercial test kit) essentially rules out an infection acquired during gestation. A low IgG avidity result should not be interpreted as indicating recent infection, because some individuals have persistent low IgG avidity for many months after infection. Suspected recent infection in a pregnant woman should be confirmed prior to intervention by having samples tested at a toxoplasmosis reference laboratory. If the patient has clinical illness compatible with toxoplasmosis but the IgG titer is low, a follow-up titer two to three weeks later should show an increase in antibody titer if the illness is due to acute toxoplasmosis, assuming the host is not severely immunocompromised.

Toxoplasmosis Laboratory Diagnosis 
IgG Result IgM Result Report/interpretation for humans*
Negative Negative No serological evidence of infection with Toxoplasma.
Negative Equivocal Possible early acute infection or false-positive IgM reaction. Obtain a new specimen for IgG and IgM testing. If results for the second specimen remain the same, the patient is probably not infected with Toxoplasma.
Negative Positive Possible acute infection or false-positive IgM result. Obtain a new specimen for IgG and IgM testing. If results for the second specimen remain the same, the IgM reaction is probably a false-positive.
Equivocal Negative Indeterminate: obtain a new specimen for testing or retest this specimen for IgG in a different essay.
Equivocal Equivocal Indeterminate: obtain a new specimen for both IgG and IgM testing.
Equivocal Positive Possible acute infection with Toxoplasma. Obtain a new specimen for IgG and IgM testing. If results for the second specimen remain the same or if the IgG becomes positive, both specimens should be sent to a reference laboratory with experience in diagnosis of toxoplasmosis for further testing.
Positive Negative Infected with Toxoplasma for six months or more.
Positive Equivocal Infected with Toxoplasma for probably more than 1 year or false-positive IgM reaction. Obtain a new specimen for IgM testing. If results with the second specimen remain the same, both specimens should be sent to a reference laboratory with experience in the diagnosis of toxoplasmosis for further testing.
Positive Positive Possible recent infection within the last 12 months, or false-positive IgM reaction. Send the specimen to a reference laboratory with experience in the diagnosis of toxoplasmosis for further testing.
  • *except infants

Newborn infants suspected of congenital toxoplasmosis should be tested by both an IgM- and an IgA-capture EIA. Detection of Toxoplasma-specific IgA antibodies is more sensitive than IgM detection in congenitally infected babies. None of the current commercial assays offered in the United States have been cleared by the Food and Drug Administration for in vitro diagnostic use for infants; consequently, all specimens from neonates suspected of having congenital toxoplasmosis should be sent to the Toxoplasma Serology Laboratory, Palo Alto, CA which has the most experience with infant testing.

Serological determination of active central nervous system toxoplasmosis in immunocompromised patients is not possible at this time. Toxoplasma-specific IgG antibody levels in AIDS patients often are low to moderate, but occasionally no specific IgG antibodies can be detected. Tests for IgM antibodies are generally negative.

Several commercial kits for Toxoplasma serologic testing are available. However, the sensitivity and specificity of these kits may vary widely from one commercial brand to another. This is of concern because serology results can influence decisions on continuation or termination of pregnancies.

References:

  1. NCCLS. Clinical Use and Interpretation of Serologic Tests for Toxoplasma gondii; Approved Guideline. NCCLS document M36-A [ISBN 1-56238-523-2]. NCCLS, 940 West Valley Road, Suite 1400, Wayne, PA 19087-1898 USA, 2004.
  2. McAuley JM, Jones JL, Singh AM. Toxoplasma. In: Jorgensen JH, Pfaller MA, Carroll KC, Funke G, Landry ML, Richter SS, Warnock DW, editors. Manual of Clinical Microbiology. 11th ed. Washington, D.C.: American Society for Microbiology; 2015. p. 2373–2386.
  3. Remington JS, McLeod R, Wilson CB, Desmonts G. Toxoplasmosis. In: Remington JS, Klein JO, editors. Infectious Diseases of the Fetus and Newborn Infant. 7th ed. Philadelphia, PA: The WB Saunders Co.; 2011. p. 918-1041.

Treatment Information

Treatment information for toxoplasmosis can be found at:

Clinical Care of Toxoplasmosis

 

DPDx is an educational resource designed for health professionals and laboratory scientists. For an overview including prevention, control, and treatment visit www.cdc.gov/parasites/.