Filariasis

(Redirected from Filarial)

Filariasis, is a filarial infection caused by parasitic nematodes (roundworms) spread by different vectors. They are included in the list of neglected tropical diseases.

Filariasis
Life cycle of Wuchereria bancrofti, a parasitic roundworm that causes lymphatic filariasis
SpecialtyInfectious disease

The most common type is lymphatic filariasis caused by three species of Filaria that are spread by mosquitoes. Other types of filariasis are onchocerciasis also known as river blindness caused by onchocerca volvulus; Loa loa filariasis (Loiasis) caused by Loa loa; Mansonelliasis caused by three species of Mansonella, and Dirofilariasis caused by two types of Dirofilaria.

Epidemiology

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In the year 2000, 199 million infection cases of lymphatic filariasis were predicted with 3.1 million cases in America and around 107 million in South East Asia, making up to 52% of the global cases coming from Bangladesh, India, Indonesia, and Myanmar combined. While the African nations that comprised around 21% of the cases showed a decrease in the trend over a period of 19 years from 2000 to 2018, studies still proved the global burden of infection to be concentrated in southeast Asia.[1]

Cause

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Eight known filarial worms have humans as a definitive host. These are divided into three groups according to the part of the body they affect:

 
Filariasis is caused by parasitic nematodes

These worms are transmitted by infected mosquitoes of the genera Aedes, Culex, Anopheles and Mansonia. Recent evidence suggests that climate change has an influence in the spread of the parasitic disease and its vectors. Lymphatic filariasis has been the leading cause of permanent disfigurement and continues to be the second most common cause of long-term disability in the world, even after several efforts of curbing the problem.[2]

Life cycle

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Wuchereria bancrofti (Wb) belonging to the family Onchocercidae, accounts for more than 90% of the filarial infections worldwide. Its complete its life cycle in two hosts, man being the definitive host while the mosquitoes act as the intermediate host. The most common mosquito vectors that aid in transmission are Anopheles in Africa, Culex in America, Aedes and Mansonia in Asia (Zulfiqar et al., 2023). Female worms are ovoviviparous and can produce thousands of juveniles known as microfilariae, in infected humans. These are ingested by mosquitoes when they bite. The ingested microfilaria mature and eventually migrate to the insect proboscis from where they get injected into the human skin. Here they travel through the dermis to the lymph organs and further mature into male and female worm forms for the next 6 to 12 months and finally reproduce to complete the cycle.[3]

Individuals infected by filarial worms may be described as either "microfilaraemic" or "amicrofilaraemic", depending on whether microfilariae can be found in their peripheral blood. Filariasis is diagnosed in microfilaraemic cases primarily through direct observation of microfilariae in the peripheral blood.

Signs and symptoms

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The most spectacular symptom of lymphatic filariasis is elephantiasisedema with thickening of the skin and underlying tissues—which was the first disease discovered to be transmitted by mosquito bites.[4] Elephantiasis results when the parasites lodge in the lymphatic system.[citation needed]

Cases of acute inflammatory filariasis manifest 5 to 7 day episodes of fever along with inflammation of lymph nodes. It is often accompanied by epididymitis and spermatic cord inflammation. Secondary bacterial infections are very common and are seen to be more severe in previously unexposed immigrants than in native residents. Chronic filarial disease develops gradually over the years. In most patients the lymphatic dilation does not present any physical symptoms. However, inflammatory responses to dying adult worms often lead to chronic lymphedema in the affected regions which then progresses to elephantiasis. W. bancrofti often causes hydrocele and scrotal elephantiasis. Moreover, disruption of lymphatic vessels or aberrant drainage of lymph fluid often leads to chyluria and chyloceles.[5]

Elephantiasis affects mainly the lower extremities, while the ears, mucous membranes, and amputation stumps are affected less frequently. However, different species of filarial worms tend to affect different parts of the body; Wuchereria bancrofti can affect the legs, arms, vulva, breasts, and scrotum (causing hydrocele formation), while Brugia timori rarely affects the genitals.[citation needed] Those who develop the chronic stages of elephantiasis are usually free from microfilariae (amicrofilaraemic), and often have adverse immunological reactions to the microfilariae, as well as the adult worms.[4]

The subcutaneous worms present with rashes, urticarial papules, and arthritis, as well as hyper- and hypopigmentation macules. Onchocerca volvulus manifests itself in the eyes, causing "river blindness" (onchocerciasis), one of the leading causes of blindness in the world.[citation needed] Serous cavity filariasis presents with symptoms similar to subcutaneous filariasis, in addition to abdominal pain, because these worms are also deep-tissue dwellers.[citation needed]

Diagnosis

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Microfilaria of Dirofilaria immitis (Heartworms) in a lymph node of a dog with lymphoma. This baby nematode is in a pillow of intermediate-to-large, immature lymphocytes, exhibiting multiple criteria of cancer.[6]

Filariasis is usually diagnosed by identifying microfilariae on Giemsa stained, thin and thick blood film smears, using the "gold standard" known as the finger prick test. The finger prick test draws blood from the capillaries of the finger tip; larger veins can be used for blood extraction, but strict windows of the time of day must be observed. Blood must be drawn at appropriate times, which reflect the feeding activities of the vector insects. Examples are W. bancrofti, whose vector is a mosquito; night is the preferred time for blood collection. Loa loa's vector is the deer fly; daytime collection is preferred.[7] This method of diagnosis is only relevant to microfilariae that use the blood as transport from the lungs to the skin. Some filarial worms, such as M. streptocerca and O. volvulus, produce microfilariae that do not use the blood; they reside in the skin only. For these worms, diagnosis relies upon skin snips and can be carried out at any time.[citation needed]

In past, one of the first successes in the efforts to improve sensitivity and specificity of filarial diagnostic tests was identification of the repeated sequences in the parasite genome. The advancement in technologies like polymerase chain reaction (PCR) led to the development of various assays that made large scale surveys of parasitic prevalence much easier.[8]

Filarial parasites are known to induce several immunoregulatory mechanisms like the activation of macrophages and T regulatory cells. It has been found that T regulatory cells play an essential role in how filarial worms modify the host immune response by producing immunoglobulin G4 (IgG4). A very high plasma content of IgG4 has been recorded in asymptomatic patients of LF. Thus, the newer assays measuring IgG4 responses to crude filarial extracts or using fractions of parasite extracts have a better overall specificity but are not efficient in discriminating microfilaremic from amicrofilaremic serum donors. Assays which measure circulating antigen are expected to be better at measuring active infection because only living worms secrete circulating antigen.[9]

As an attempt to come up with immunodiagnostic test kits for detection of circulating filarial antigen, numerous Antigens and Antibodies specific to the parasites have been tested. An Og4C3 monoclonal antibody-based ELISA and an immunochromatographic ( ICT) card test using the same monoclonal antibody have been tested. However, these commercial assays have certain issues with respect to stability, cost and specificity in field applications. Moreover, it was seen that the ICT format showed 25% of microfilarial negative individuals as being positive for circulating filarial antigens.[10]

These commercial tests based on the above circulating antigens are also limited to successful detection of only adult bancroftian worms, making diagnosis only possible in later stages of infection when the therapeutics might no more show effect. A search for worm specific antigens was initiated where SXP-1 antigen was recognized to be specific for W.bancrofti filariasis. The antigen was identified after screening the cDNA library of adult worms with serum from both amicrofilaremic and microfilaremic patients.The native SXP-1 antigen was present in extracts of microfilariae and adult worms and were seen to be not specific to any lifecycle stage.[11]

To identify a W. bancrofti-specific antigen, pastor et al., used the Bm SXP gene to screen against the W.bancrofti Larval stage 3 cDNA library. This led to the identification of a cDNA sequence of W.bancrofti SXP-1 that encoded for a polypeptide with a predicted molecular weight of 20.8 kDa. Wb-SXP was found to be 85 percent identical to the BmSXP polypeptide and differed along the C terminal where the former had an extra 29 amino acid long extension. The WbSXP-1 variant, where a stop codon has been introduced at the amino acid position 153 has been shown to be widely distributed among different W.bancrofti populations. Searches carried out with available sequences from various worms revealed the presence of SXP-1 homologs in many other nematodes with substantial identities in sequence observed during pairwise comparisons. Some examples include O.volvulus (50% identity; Ov-SXP-1), Ascaris suum (43%; As-SXP-1), Loa loa (46%; Li-SXP-1), and C.elegans (29%; Ce-SXP-1).The presence of a number of invariant and conserved residues in all of these nematode-derived molecules suggests that Wb-SXP-1 is a member of a new protein family.[12]

Treatment

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The recommended treatment for people outside the United States is albendazole combined with ivermectin.[13][14] A combination of diethylcarbamazine and albendazole is also effective.[13][15] Side effects of the drugs include nausea, vomiting, and headaches.[16] All of these treatments are microfilaricides; they have no effect on the adult worms. While the drugs are critical for treatment of the individual, proper hygiene is also required.[17] One review study found that "there is good evidence" that albendazole itself does not contribute to the elimination of microfilaraemia or adult filarial worms, and thus is likely an unnecessary component of albendazole-ivermectin treatment.[18] Diethylcarbamazine-medicated salt is effective in controlling lymphatic filariasis while maintaining its coverage at 90% in the community for six months.[19]

Different trials were made to use the known drug at its maximum capacity in absence of new drugs. In a study from India, it was shown that a formulation of albendazole had better anti-filarial efficacy than albendazole itself.[20][non-primary source needed]

In 2003, the common antibiotic doxycycline was suggested for treating elephantiasis.[21] Filarial parasites have symbiotic bacteria in the genus Wolbachia, which live inside the worm and seem to play a major role in both its reproduction and the development of the disease. This drug has shown signs of inhibiting the reproduction of the bacteria, further inducing sterility in the nematode.[15] Clinical trials in June 2005 by the Liverpool School of Tropical Medicine reported an eight-week course almost eliminated microfilaraemia.[22][non-primary source needed] [23]

Society and culture

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Research teams

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In 2015 William C. Campbell and Satoshi Ōmura were co-awarded half of that year's Nobel prize in Physiology or Medicine for the discovery of the drug avermectin, which, in the further developed form ivermectin, has decreased the occurrence of lymphatic filariasis.[23]

Prospects for elimination

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Filarial diseases in humans offer prospects for elimination by means of vermicidal treatment. If the human link in the chain of infection can be broken, then notionally the disease could be wiped out in a season. In practice it is not so simple, and there are complications in that multiple species overlap in certain regions and double infections are common. This creates difficulties for routine mass treatment because people with onchocerciasis in particular react badly to treatment for lymphatic filariasis.[24]

Other animals

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Filariasis can also affect domesticated animals, such as cattle, sheep, and dogs.[citation needed]

Cattle

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  • Verminous hemorrhagic dermatitis is a clinical disease in cattle due to Parafilaria bovicola.
  • Intradermal onchocerciasis of cattle results in losses in leather due to Onchocerca dermata, O. ochengi, and O. dukei. O. ochengi is closely related to human O. volvulus (river blindness), sharing the same vector, and could be useful in human medicine research.
  • Stenofilaria assamensis and others cause different diseases in Asia, in cattle and zebu.

Horses

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Dogs

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See also

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References

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  1. ^ Prevention, CDC-Centers for Disease Control and (17 September 2020). "CDC - Lymphatic Filariasis - General Information - Frequently Asked Questions". www.cdc.gov.
  2. ^ Lourens, G. B., & Ferrell, D. K. (2019). Lymphatic Filariasis. The Nursing Clinics of North America, 54(2), 181–192.https://doi.org/10.1016/j.cnur.2019.02.007
  3. ^ Hawking, F., & Garnham, P. C. C. (1997). The 24-hour periodicity of microfilariae: Biological mechanisms responsible for its production and control. Proceedings of the Royal Society of London. Series B. Biological Sciences, 169(1014), 59–76. https://doi.org/10.1098/rspb.1967.0079
  4. ^ a b "Lymphatic filariasis". Health Topics A to Z. Source: The World Health Organization. Retrieved 24 March 2013.
  5. ^ ( Red Book: 2021–2024 Report of the Committee on Infectious Diseases, Lymphatic Filariasis (Bancroftian, Malayan, and Timorian), 2021
  6. ^ Wheeler L. "Microfilaria of Dirofilaria immitis (Heartworms) Surrounded by Neoplastic Lymphocytes". Flickr. Retrieved 2 December 2017.
  7. ^ Metzger, Wolfram Gottfried; Mordmüller, Benjamin (April 2014). "Loa loa—does it deserve to be neglected". The Lancet Infectious Diseases. 14 (4): 353–357. doi:10.1016/S1473-3099(13)70263-9. PMID 24332895.
  8. ^ Pastor, A. F., Silva, M. R., dos Santos, W. J. T., Rego, T., Brandão, E., de-Melo, Neto, O. P., & Rocha, A. (2021). Recombinant antigens used as diagnostic tools for lymphatic filariasis. Parasites & Vectors, 14(1), 474. https://doi.org/10.1186/s13071-021-04980-3
  9. ^ Harnett, W., Bradley, J. E., & Garate, T. (1998). Molecular and immunodiagnosis of human filarial nematode infections. Parasitology, 117 Suppl, S59-71. https://doi.org/10.1017/s0031182099004084
  10. ^ Janardhan, S., Pandiaraja, P., Pandey, V., Karande, A., & Kaliraj, P. (2011). Development and characterization of monoclonal antibodies against WbSXP-1 for the detection of circulating filarial antigens. Journal of Helminthology, 85(1), 1–6. https://doi.org/10.1017/S0022149X10000118
  11. ^ Dissanayake, S., Xu, M., & Piessens, W. F. (1992). A cloned antigen for serological diagnosis of Wuchereria bancrofti microfilaremia with daytime blood samples. Molecular and Biochemical Parasitology, 56(2), 269–277. https://doi.org/10.1016/0166-6851(92)90176-k
  12. ^ Rao, K. V., Eswaran, M., Ravi, V., Gnanasekhar, B., Narayanan, R. B., Kaliraj, P., Jayaraman, K., Marson, A., Raghavan, N., & Scott, A. L. (2000). The Wuchereria bancrofti orthologue of Brugia malayi SXP1 and the diagnosis of bancroftian filariasis. Molecular and Biochemical Parasitology, 107(1), 71–80. https://doi.org/10.1016/s0166-6851(99)00231-5
  13. ^ a b The Carter Center, Lymphatic Filariasis Elimination Program, retrieved 17 July 2008
  14. ^ U.S. Centers for Disease Control, Lymphatic Filariasis Treatment, retrieved 17 July 2008
  15. ^ a b Taylor MJ, Hoerauf A, Bockarie M (October 2010). "Lymphatic filariasis and onchocerciasis". Lancet. 376 (9747): 1175–85. doi:10.1016/s0140-6736(10)60586-7. PMID 20739055. S2CID 29589578.
  16. ^ Turkington CA. "Filariasis". The Gale Encyclopedia of Public Health. 1: 351–353.
  17. ^ Hewitt K, Whitworth JA (1 August 2005). "Filariasis". Medicine. 33 (8): 61–64. doi:10.1383/medc.2005.33.8.61.
  18. ^ Macfarlane CL, Budhathoki SS, Johnson S, Richardson M, Garner P (January 2019). "Albendazole alone or in combination with microfilaricidal drugs for lymphatic filariasis". The Cochrane Database of Systematic Reviews. 1 (1): CD003753. doi:10.1002/14651858.CD003753.pub4. PMC 6354574. PMID 30620051.
  19. ^ Adinarayanan S, Critchley J, Das PK, Gelband H, et al. (Cochrane Infectious Diseases Group) (January 2007). "Diethylcarbamazine (DEC)-medicated salt for community-based control of lymphatic filariasis". The Cochrane Database of Systematic Reviews. 2007 (1): CD003758. doi:10.1002/14651858.CD003758.pub2. PMC 6532694. PMID 17253495.
  20. ^ Gaur RL, Dixit S, Sahoo MK, Khanna M, Singh S, Murthy PK (April 2007). "Anti-filarial activity of novel formulations of albendazole against experimental brugian filariasis". Parasitology. 134 (Pt 4): 537–44. doi:10.1017/S0031182006001612. PMID 17078904. S2CID 24567214.
  21. ^ Hoerauf A, Mand S, Fischer K, Kruppa T, Marfo-Debrekyei Y, Debrah AY, Pfarr KM, Adjei O, Buttner DW (2003), "Doxycycline as a novel strategy against bancroftian filariasis-depletion of Wolbachia endosymbionts from Wuchereria bancrofti and stop of microfilaria production", Med Microbiol Immunol (Berl), 192 (4): 211–6, doi:10.1007/s00430-002-0174-6, PMID 12684759, S2CID 23349595
  22. ^ Taylor MJ, Makunde WH, McGarry HF, Turner JD, Mand S, Hoerauf A (2005), "Macrofilaricidal activity after doxycycline treatment of Wuchereria bancrofti: a double-blind, randomised placebo-controlled trial", Lancet, 365 (9477): 2116–21, doi:10.1016/S0140-6736(05)66591-9, PMID 15964448, S2CID 21382828
  23. ^ a b Andersson J, Forssberg H, Zierath JR (5 October 2015), "Avermectin and Artemisinin - Revolutionary Therapies against Parasitic Diseases" (PDF), The Nobel Assembly at Karolinska Institutet, retrieved 5 October 2015
  24. ^ Ndeffo-Mbah ML, Galvani AP (April 2017). "Global elimination of lymphatic filariasis". The Lancet. Infectious Diseases. 17 (4): 358–359. doi:10.1016/S1473-3099(16)30544-8. PMID 28012944.
  25. ^ Pringle H (3 March 2011), The Emperor and the Parasite, retrieved 9 March 2011

Further reading

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  • "Special issue", Indian Journal of Urology, 21 (1), January–June 2005
  • "Filariasis". Therapeutics in Dermatology. June 2012. Retrieved 24 July 2012.
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