Thursday, October 3, 2019
Current Diagnostic Methods for Human Immunodeficiency Virus
Current Diagnostic Methods for Human Immunodeficiency Virus Abstract: Detection of human immunodeficiency virus (HIV) infection is essential for diagnosis and monitoring of the infection. There are several different types of diagnostic tools available that are based on detection of HIV-specific antibodies, virus antigen, or nucleic acid. Sensitivities and specificities of assays utilized for HIV detection have improved. Newer HIV testing technologies such as third-generation enzyme immunoassay (EIA) which detect HIV-specific IgG and IgM antibodies, fourth-generation EIA which detect both anti-HIV antibodies and HIV p24 antigen, and nucleic acid-based tests (NATs) for HIV RNA, have significantly decreased the window period. This review study provides an overview of current technologies for the detection and monitoring of HIV infection and recent advances in the field of HIV diagnosis. Keywords: HIV diagnosis; HIV antibody test; human immunodeficiency virus; Immunoassay; Polymerase chain reaction (PCR) Introduction: Diagnosis of HIV infection contributes to evaluating the progression of disease, monitoring the effectiveness of antiretroviral therapy (ART), and prevention and control of HIV/AIDS. The diagnosis of HIV is associated with decrease in risky behaviors, reduced HIV transmission, and improved survival linked to increased case detection, earlier care and treatment. HIV-negative persons can also protect themselves from HIV when making sexual decisions by engaging in safer sex behaviors and sometimes, taking pre-exposure prophylaxis (PrEP). Early diagnosis of HIV infection provides an opportunity for risk reduction counseling and preventing further transmission of the disease, while late diagnosis of HIV infection is detrimental to infected patients and to the public health, and is associated with an increased rate of morbidity, mortality, and healthcare costs. Since the start of the epidemic, it is estimated that 78 million people have become infected with HIV and 35 million people have died from AIDS-related illnesses. In 2015, 2.1 million people became newly infected, 36.7 million people were living with HIV and 1.1 million people died from AIDS-related illnesses. New HIV infections have fallen by 6% since 2010. Sub-Saharan Africa, which bears the heaviest burden of HIV/AIDS worldwide, accounts for 65% of all new HIV infections. Other regions significantly affected by HIV/AIDS include Asia and the Pacific, Latin America and the Caribbean, and Eastern Europe and Central Asia (Table 1) [9]. The present study aims to conduct a narrative review to summarize and discuss the current diagnostic methods for HIV and recent developments. We start with a brief overview of HIV infection, follow by a description on the development of virological and immunological markers following HIV infection. Thereafter, we introduce current algorithms for laboratory HIV testing with different kind of current diagnostics techniques including various generations of enzyme immunoassays, rapid or point-of-care tests, and qualitative/quantitative PCR assays. Overview of HIV Infection: HIV-1 causes chronic infection which is usually characterized by progressive immune deficiency, a long period of clinical latency, and appearance of opportunistic infections [1, 2]. Characteristics of HIV include infection and viral replication in T lymphocyte expressing CD4 antigen. Qualitative defects in CD4 cell response and a gradual decline in their numbers increase the risk of opportunistic infections like Pneumocystis carinii pneumonia, and neoplasms such as Kaposis sarcoma and lymphoma [3-5]. HIV infection can disrupt functions of blood monocytes, tissue macrophages, and B lymphocytes, and also increase the potential of encapsulated bacteria for developing infections [6, 7]. Direct invasion of CD4 cells in the peripheral and central nervous systems can cause meningitis, peripheral neuropathy, and dementia [8]. The prognosis is variable between people infected with HIV-1. In adults, the average time between HIV exposure to AIDS stage is 10-11 years, but a remarkable proportion of individuals (~20%) progresses rapidly to AIDS within 5 years after HIV exposure. On the other hand, it is estimated that 12% of infected individuals will remain free of AIDS for 20 years [10]. Prophylaxis and in particular antiretroviral therapy (ART) significantly enhanced the overall prognosis of HIV disease against opportunistic infections [11]. The most common route of HIV infection is sexual transmission at the genital mucosa via direct contact with infected body fluids, such as blood, semen, and vaginal secretions. Infection may also occur via inoculation of infected blood, transfusion of infected blood products, transplantation of infected tissues, from an infected mother to her infant during pregnancy, or by reuse of contaminated needles [12]. The probability of transmission after a single exposure with an uncontrolled HIV source has been estimated to be 1/150 with needle sharing, 1/300 with occupational percutaneous exposure, 1/300-1/1000 with receptive anal intercourse, 1/500-1/1250 with receptive vaginal intercourse, 1/1000-1/3000 with insertive vaginal intercourse, and 1/3000 with insertive anal intercourse. The average risk is 12-50% for congenital (mother-to-child) transmission, 12% for breast-feeding, 90% for a contaminated blood transfusion, and 0.1-1.0% for nosocomial transmission [13]. The risk of HIV transmission during early or acute HIV infection appears to be greater than during chronic infection (251). Available data suggest that the viral load is an important predictor of the risk of heterosexual transmission, and patients with levels less than 1500 copies of HIV-1 RNA per milliliter are at lower risk of HIV transmission, whereas the probability of transmission is increased dramatically with increasing vira l loads (250). Laboratory markers for HIV-1 infection: Several immunological and virological blood markers can be monitored during the course of HIV infection. These markers appear highly consistent between different individuals in a chronological order and allows classification of HIV infection into distinct laboratory stages including eclipse period, seroconversion window period, acute HIV infection, and established HIV infection (Figure 1) [14, 15]. Shortly after exposure to HIV-1, no viral markers are consistently detectable in plasma, but low levels of HIV-1 RNA can be found intermittently [16]. This period is called the eclipse phase. About 10 days after infection, HIV-1 RNA becomes detectable by NAT in plasma and quantities rise to very high levels [17], which subsequently decline rapidly until reaching a set point, a stable level that may persist for years. This stable level of HIV RNA represents an equilibrium between HIV and host immune responses and is an important indicator of subsequent disease progression, and potential transmission of HIV. It has been shown that the higher HIV-1 RNA plasma level is associated with faster progression to AIDS [18]. The set point plasma HIV-1 RNA level can be a helpful clinical tool for determining the timing of initiation of antiretroviral therapy for HIV-infected patients. For instance, patients with high set point levels can be started on aggressive antiretroviral therapy and patient s with low set point levels can be monitored without initiating therapy [19]. HIV-1 p24 antigen is expressed and quantities rise to levels that can be measured by fourth-generation immunoassays within 17 days after infection (typical range 13-28 days) [15, 20]. Due to high titers of p24 antigen present in the sera of acutely infected patients during the interval prior to seroconversion, p24 Ag assay can be utilized to diagnose the primary HIV-1 infection [21]. Nevertheless, detection of p24 antigen is transient because, as antibodies begin to develop, they bind to the p24 antigen and form immune complexes that interfere with p24 Ag assay [22, 23]. The time interval between infection with HIV and the first detection of antibodies is known as the serological window period. The detection of HIV-specific antibodies indicates the end of the window period and the individual is known as seropositive [24]. The length of the window period depends on the design and the sensitivity of the immunoassay. Expression of IgM antibodies can be detected by immunoassays within 10 to 13 days after the appearance of viral RNA, 3 to 5 days after detection of p24 antigen, and peak between the 4th and the 5th week [15, 20, 25, 26]. Thereafter, the emergence of IgG antibodies occurs at about 3-4 weeks after infection and persist throughout the course of HIV infection [21]. Nevertheless, the immune responses are highly dependent on the ability of the individuals immune system to produce the antibodies. Approximately, 50% of patients within 3-4 weeks and about 100% of them within 6 months have detectable antibodies, although there are reports indicating that a small percentage of patients may require up to 6 months for the appearance of antibodies [27]. Laboratory HIV testing algorithms: Since 1989, the diagnostic algorithm for HIV testing recommended by CDC and the Association of Public Health Laboratories (APHL) relied on the confirmation of a repeatedly reactive HIV immunoassay with the more specific HIV-1 antibody test, either the HIV-1 Western blot or HIV-1 indirect immunofluorescence assay (IFA). The Western blot was previously considered to be the gold standard for the diagnosis of HIV infection by Clinicians [29, 30]. It should be noted that both the Western blot and IFA are first-generation assays that detect only IgG antibodies against HIV proteins. Retrospective testing of specimens from high-risk individuals pointed that antibody testing alone may miss a significant percentage of HIV infections detectable by virologic tests such as HIV antigen and nucleic acid assays. In 2013, the CDC and the APHL released new guidelines on HIV testing that have led to the earlier diagnosis of HIV infection when compared with the previous diagnostic algorithm. The new recommended algorithm starts with a fourth-generation HIV-1/2 Ag/Ab immunoassay to screen for HIV infection that detects both HIV-1/2 antibodies and the HIV-1 antigen. When the result of initial immunoassay is nonreactive, further testing is not required for samples. Instead, testing with an HIV-1/HIV-2 antibody differentiation test is needed when the sample is reactive on the screening fourth-generation assay. Reactive results with the initial fourth-generation assay and the HIV-1/HIV-2 antibody differentiation immunoassay should be considered as reactive for HIV-1 antibodies, HIV-2 antibodies, or HIV antibodies, undifferentiated. Reactive results with the initial fourth-generation assay and nonreactive or indeterminate on the HIV-1/HIV-2 antibody differentiation immunoassay should be tested with an FDA-approved HIV-1 NAT to differentiate early HIV infection from a false-positive screening result [28] (Figure 2). HIV diagnostic tests: Serological diagnostic assays: Enzyme Immunoassays (EIA):Significant advances in the development of HIV immunoassays have been created since the discovery of HIV in 1983. Based on different design principles, HIV immunoassays are generally classified into generations. The earliest immunoassays (first-generation) are indirect EIAs that used coated viral lysate antigens derived from cell culture on a solid phase for antibody capture and an indirect format that detected antibody utilizing an enzyme-conjugated antihuman IgG [36]. Antibody can be detected within 8-10 weeks postinfection by first generation immunoassay. These assays have 99% sensitivity and 95-98% specificity for HIV infection. Second-generation immunoassays use synthetic peptide or recombinant protein antigens alone or in combination with viral lysates to bind HIV antibodies, and they use an indirect immunoassay format that employs conjugated antihuman IgG, which binds to IgG with high affinity, to detect IgG antibodies [37]. Utilizing recombinant anti gens in the second-generation assays improves sensitivity for HIV-1, HIV-1 group O, and HIV-2, allowing earlier detection of IgG antibodies. The sensitivity and specificity of second-generation assays have been reported to be Ãâ¹Ãâ99.5% and Ãâ¹Ãâ99%, respectively. First and second generation immunoassays can only detect IgG antibody to HIV. The window period was decreased to 4 to 6 weeks postinfection by second-generation assays. Third generation immunoassays also utilize synthetic peptide or recombinant antigens to bind HIV antibodies, but in an immunometric antigen sandwich format; HIV antibodies in the specimen bind to HIV antigens on the assay substrate and to antigens conjugated to indicator molecules. This allows detection of both IgM and IgG antibodies which leads to increase in sensitivity and specificity of the test. Lower sample dilutions and the ability to detect IgM antibodies (which are expressed before IgG antibodies) further decrease the window period to 2-3 weeks postinfection [38]. The reported sensitivity and specificity of third-generation assays is Ãâ¹Ãâ99.5%. Combination or fourth-generation tests use synthetic peptide or recombinant protein antigens in the same antigen sandwich format as third-generation assays for the detection of IgM and IgG antibodies, and also monoclonal antibodies for the detection of p24 antigen [39]. Inclusion of p24 antigen capture allows the detection of HIV-1 infection before seroconversion and further decreases the window period. Most fourth-generation antigen/antibody immunoassays (termed combo assays) do not distinguish antibody reactivity from antigen reactivity [39]. Recent published data has shown that the fourth-generation assay was able to establish HIV infection in more than 80% of patients who tested NAAT positive but either nonreactive or indeterminate by other tests like Western blot, first to third generation immunoassays, and rapid tests [40-42]. Delaney et al. found that the fourth-generation immunoassay are able to detect HIV infection 1-3 weeks earlier than the first, second, and third generation immunoassay which cannot detect p24 antigen. The results of their study revealed that the median duration of the eclipse period was 11.5 days and 99% of specimens from HIV-infected patients could be reactive with Ag/Ab combination tests within 45 days of exposure. Moreover, for detection of antibodies by the IgG/IgM-sensitive and other plasma screening assays, 50 days or longer were required and after 3 month of exposure, infection could be detected by all tests. Several studies have reported sensitivities of 100% for fourth-generation immunoassay, whereas other surveys reported transient sensitivities range from 62-89% when assessed against HIV RNA assays. This decreased sensitivity can be attributed to the presence of a second diagnostic window. This situation is rare but it can happen. Second diagnostic window period lies between the p24 antigen detection and the anti-HIV antibody detection, and is associated with reduction in the p24 antigen and antigen/antibody complexes levels, as well as a delay in HIV-specific antibody development which totally may affect the sensitivity of fourth-generation immunoassays. So, it is possible that many acute HIV infections have been missed using fourth-generation assays. Despite negative results from a fourth-generation immunoassay in high-risk populations with suspected acute HIV infection, it is needed to repeat the test on new blood samples obtained several days later, as well as testing for HIV anti body alone, p24 antigen or use of an HIV RNA assay. In 2015, an improved version of immunoassay, BioPlex 2200 HIV Ag-Ab screening test system, received FDA approval in HIV screening which detects both HIV antibody and the HIV-1 p24 antigen by providing separate results for each analyte. This test also provides separate results for HIV-1 and HIV-2 antibodies, so there is no need for a HIV-1/2 differentiation assay for antibody reactive samples. It was reported that the sensitivity and specificity of BioPlex 2200 HIV Ag-Ab assay were 100 and 99.5%, respectively [43]. HIV Confirmatory Tests:Screening tests must be highly sensitive to produce few false-negative results, whereas confirmatory assays are characterized with high specificity to produce few false-positive results [44]. If the result of a screening test is repeatedly reactive, this has to be confirmed by (at least) one confirmatory assay. Western blot or indirect IFA traditionally have been employed as confirmatory assay due to their higher specificity. The probability that both ELISA and Western blot would give false-positive results is extremely low (
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