Lassa fever

Introduction

This paper discusses Lassa fever, an infectious disease with regard to its causality organism, transmission, epidemiology, and factors causing the illness, clinical manifestation and diagnosis and the role of the nurse in controlling the illness. Lassa fever is a severe viral hemorrhagic infection caused by Lassa virus, which is affiliated to arenavidae virus family. West African communities from countries such as Nigeria, Ghana, Guinea, and Liberia among others have registered high prevalence rates of the infection typified by approximately 300-500 thousand cases and 5000 deaths annually.

Organism and transmission

Lassa virus, the causality of the Lassa fever belongs to genus arenavirus and arenavidae family (Clercq & Kern, 2003). The virus is enveloped, mono-stranded, and double-segmented having Ribonucleic Acid as genetic material. The virus might display various dissimilar shapes hence varied pleomorphism characteristics measuring approximately 80 to nanometer in thickness. The viral envelope or covering is studded with glycoproteins comprising of tetrameric composites that belong to viral glycoproteins GP1 and GP2. The virus has the capability of managing its replication process rapidly, which is two-step progression. The initial step is the transcription of mRNA copies to minus-sense genome. This process is essential to the virus since it guarantees sufficient provision of viral proteins for the forthcoming replication step, which involves transformation of proteins N and L from the mRNA (Dworkin, 2011). This is followed by the formation of viral complimentary RNA copies abbreviated as vcRNA from the plus-sense genome. The viral complementary RNA acts as a model for generation of minus sense offspring and synthesis of mRNA. The generated mRNA from vcRNA is transformed to form the G proteins and Z proteins. The above two processes reveal the control of the virus over its replication process, hence not easily recognized in the host immune system. Nucleotide research on the virus has revealed that Lassa virus contains four lineages recognized in Nigeria, Guinea, Liberia, and Sierra Leone.

Ergonul & Whitehouse (2007) affirms that Lassa virus has receptors on its cell surface called the alpha-dystroglycan (alpha-DG) used for gaining access into the host cell. The receptor is flexible and is composed of the proteins of the extracellular matrix. The flexibility of the receptor is extended to its usage by the prototypic arenavirus lymphocytic choriomeningitis virus. Lassa virus’ receptors are distinguished by a particular sugar alteration on alpha-DG referred to as glycosyltransferases (Frey & Price, 2003). Additionally, alpha-DG is employed as a receptor by New World clade C viruses. Lassa virus uses an endocrytic pathway that lacks clathrin, caveolin, dynamin, and actin unlike other enveloped viruses. The virus carries a speedy delivery of endosomes once in the host cell through vesicular.

The modes of transmission of the infection to human beings exist in different forms. The two modes are natural reservoir and vectors. The multimammate rat scientifically referred to as mastomys natalensis is the natural reservoir of Lassa virus, which causes Lassa fever. The precise species of the rodent associated with disease has not yet been discovered, but it is largely believed that species natalensis is responsible for fever. The distribution of the virus depends on various reasons. Rodents are present inside houses where people live and some of these rodents are the reservoir of the Lassa virus (Georgiev, 2009). The multimammate rat breeds regularly, infecting their progeny with during birth. The resultant effect is long chain of the viral infection to host and host to people.

Vector mode transmission involves the shedding of the virus in the rodents’ excreta, urine, and feces. The transmission is considered zoonotic since it spreads from rats to humans. Rats have an asymptomatic state of the virus, which is the reason why they can survive without being affected. According to Lashley & Durham (2002), Human infections normally results from contact to the rodents’ excretion wastes through the respiratory or gastrointestinal systems. Aerolization of the feces and urine makes the viral tiny particles vulnerable inhalation by human beings. However, injured skins or mucous membranes expose the body fluid infective substances. Some propositions also exist advocating that the disease can be transmitted through sexual intercourse.

The West African community registers the highest prevalence of the infection due to poor housing and hygiene (Ergonul & Whitehouse, 2007). Research reveals that building materials used by the community uses materials such as woods and mud in construction. However, some concrete building also exists. Mud walls with holes provided habitat for the rodent carrying the virus. Lower parts of West Africa have some dense vegetation, which also provide habitat.

Epidemiology and contributing factors

The most relentlessly affected countries of West Africa include Liberia, Sierra Leone, Guinea, and Nigeria. These countries are characterized by constant outbreaks of the illness. Notably, the endemicity of the Lassa fever is not restricted to political borders but instead by geographical areas. Studies affirm that other countries in West Africa, other than the severely hit have experienced sporadic outbreaks among humans or human sero-prevalence or rodents. Detection of Lassa Virus in rodents in southern Mali implies that the prevalence of the infection is likely to increase (Mahy & Regenmortel, 2009).

The Marshall Cavendish Corporation (2007) point out that, impaired or delayed cellular immunity that results to fulminant viremia is major characteristic of the illness. The occurrence rates of the illness in Sierra Leone, Guinea, and Nigeria are 8-15%, 4-55%, and 21% respectively (Schwartz, 2009). Central African Republic, DRC, and Senegal have been noted to have cases of sero-positivity. Research reveals that West Africa faces approximately half a million Lassa fever cases annually and 5000 of them finalizing to death. The disease can be spread straight from one human to another and airborne infections. It has also been observed that contact with infected blood; semen and urine increase the risk of being infected.

Contributing factors of the infection are classified as biological, cultural, and infrastructural. Biological factors include contagion of food or food source and habitat by the rodents. These rodents are popular near farmhouse where cereals are stored hence tainting the food. Consumption of such food exposes human beings to the virus, which contributes to the illness. Moreover, poor storage of harvest, a common practice in many countries of West Africa accelerates the rate of escalation of the illness (Tyring & Yen-Moore, 2002). Another biological factor is the microorganisms from rat excretions, which can survive and float in the air and be inhaled by humans. The disease is also passed on through contact of secretions of infected people.

Cultural contributing factors of Lassa fever are attributed to the way West Africans live and their beliefs. Sierra Leoneans have been ensnaring rats for food and other purposes as a tradition. Most of them did not have the knowledge of the type of rat they were eating or handling due to ignorance and lack of proper research. This tradition has led to deaths of sierra Leoneans who handled Mastomys natalensis, the causality of Lassa fever. Sanitation officers affirmed that most of Sierra Leoneans would not want the rats killed since it would mean destroying their source of food (Suckow, Weisbroth, & Franklin, 2006). Sanitation efforts in sierra Leon have proved to be a hard task for a very long time, not until people realized that the popular farmhouse rodent was the cause of the deadly disease.

Infrastructural causalities are mainly attributed to a given population ignorance and human activities. The increase in rat population contributes to the fatal illness since rodents are common in filthy and eyesore environment due to human activities of negligence such as dumping. Such environment increases the breeding of the rodents resulting to escalating cases of illnesses inclusive of Lassa fever. Overcrowding or dense population in major cities increases the rate of dumping and human-to-human infections (Mahy & Regenmortel, 2009). Airborne infections spread rapidly in a congested place since the distance between people is much shorter. Illiteracy among patients is another infrastructural factor and it evidenced by patients who would not seek medical treatment until the infection got severe. This poses a lot of difficulty in treatment since doctors had to deal with severe cases only. Improved political environment and security has enable people in Sierra Leon and Liberia to move freely, spreading the disease to uninfected areas, which increases case reporting.

Clinical manifestations and Diagnosis

Patients suffering from Lassa fever experience slow inception of fever and malaise. The fever can last for a period of 2-3 weeks accompanied by myalgia. Fatal prostration, associated to particular organs and serosa are also signs of the infection. Additionally, sternum pains with coughing are frequently indicators of Lassa fever (Webber, 2009).

Bleeding is another symptom among patients suffering from the infection. Gum bleeding is an instance and it is susceptible to some patients. The stomach, kidneys, small intestines, lungs, and brain start hemorrhaging due to abrasions in the capillaries. Fatal circumstances of the infection might result to vascular collapse and shock, preceded by death. Previous studies affirm that shock is caused by the dysfunction of the platelet and endothelial that brings forth hemorrhage allowing body fluids to seep out into the intravascular system (Tyring & Yen-Moore, 2002).

Other popular symptoms include abdominal pains, vomiting and nausea, constipation or diarrhea. Conjunctivitis and pharyngitis might also arise due to soreness of the mucous membrane and other fundamental parts of the pharynx. Accelerated vascular permeability also begins to occur because of pleural effusions. The urine of an infected person contains proteins causing proteinuria. Approximately 10-30% of infected patients have swellings in the neck and face.

The varied expression of the virus and presence of other similar symptoms have made the diagnosis of the Lassa fever difficult. ELISA test is the most preferred and used diagnostic tool. The test comprises of segregating the virus from urine, throat washings, and blood during the vehement phase of the infection. The test is effective since it pinpoints Lassa virus antibodies and patient’s serum antigen. Another diagnostic test is the Reverse Transcription Polymerase Chain Reaction (RT-PCR), though essentially employed in research studies. Leukocyte and platelet counts, albuminuria, AST level and chest X-rays among others are clinical tests deployed in the diagnosis of Lassa fever (Marshall Cavendish Corporation, 2007).

Role of the nurse

` Evading rodents, reservoir source are the only sure way of preventing the primary infection particularly in geographic areas such as Nigeria characterized by growing cases of outbreaks. Safekeeping food practices that will deny the mastomys rats’ access to food will significantly reduce the infection rate. Improving sanitation standards at homes and not using rats a source of food is essential to ensure that the disease prevented. Eradicating the reservoir source, rodent seems to be impossible due to its high population hence trapping them will be helpful in reducing their numbers. As a result, outbreaks will drop. Nurses play a key role in ensuring patients evade the rodents and their excretions by providing clean environment encouraging proper sanitation methods (Schwartz, 2009).

Nurses have a role in taking care of patients having Lassa fever. This exposes them to the risk of person-to-person transmission. As such, nurses have to adhere to some preventive measures that will safeguard them from contacting patient secretions. This method of taking care of patients while considering precautions is referred to as barrier nursing. Barrier nursing might entail wearing of masks, gloves, gowns, and protective clothes (Georgiev, 2009). Sterilization of medical equipment and patient isolation to prevent spread to people are some of the nursing practices that are aimed at stopping or reducing outbreak. It important to note that nurses play a key role in ensuring that the infection rate and number of reported cases are lowered.

Conclusion

Lassa virus causes Lassa fever and its natural reservoir is a rodent, scientifically referred to as mastomys natalensis. The virus is double stranded with capabilities of managing the replication process on its own. It also has receptors for gaining access to the host cell where they can breed. The disease is transmitted through vector and natural reservoir modes. Natural reservoir transmission occurs when the rat infects people. The prevalence rates are high in Nigeria, Liberia, Sierra Leone, and Guinea due to factors such as use of rats as source of food, poor sanitation, and high population in urban centers. Symptoms of the disease include malaise and fever, gum bleeding and intestinal lesions. Nurses reduce the occurrence of the disease by using barrier-nursing methods to prevent its spread to unprotected persons.

References

Clercq, E., & Kern, E. (2003). Handbook of viral bioterrorism and biodefense. London: Elsevier.

Dworkin, M. ( 2011). Cases in Field Epidemiology: A Global Perspective. New York: Jones & Bartlett Learning.

Ergonul, O., & Whitehouse, C. (2007). Crimean-Congo Hemorrhagic Fever: A Global Perspective. New York: Springer.

Frey, K., & Price, P. (2003). Microbiology for Surgical Technologists. New York: Cengage Learning.

Georgiev, V. (2009). National Institute of Allergy and Infectious Diseases, NIH: Impact on Global Health . New York: Springer .

Lashley, F., & Durham, J. ( 2002). Emerging infectious diseases: trends and issues. New York: Springer Publishing Company.

Mahy, B., & Regenmortel, M. (2009). Desk Encyclopedia of Human and Medical Virology. London: Academic Press.

Marshall Cavendish Corporation. ( 2007). Diseases and Disorders, Volume 2. London: Marshall Cavendish.

Schwartz, E. (2009). Tropical Diseases in Travelers. New York: John Wiley and Sons, .

Suckow, M., Weisbroth, S., & Franklin, C. ( 2006). The laboratory rat. London: Academic Press.

Tyring, S., & Yen-Moore, A. (2002). Mucocutaneous manifestations of viral diseases. New York: CRC Press.

Webber, R. (2009). Communicable disease epidemiology and control: a global perspective. New York: CABI.


 

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