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Show detailsIntroduction
CD4 count is a laboratory test that measures CD-4 T lymphocytes (T cells) via flow cytometry. This test is an important parameter in HIV management and is used to guide clinical treatment. The CD4 count is a reliable indicator of a patient’s immunologic status and is used to determine the necessity for initiation of prophylactic treatment against opportunistic infections.[1]
CD4 T cells are human helper T cells that express cluster determinant 4 (CD4) molecules. The CD4 molecule is a member of the immunoglobulin family and primarily mediates adhesion to major histocompatibility complex molecules. CD4 T cells are selectively targeted and infected by HIV. HIV proliferates rapidly during acute infection leading to high levels of viremia and rapid impairment and death of CD4 T cells.[2][3][4][5]
Specimen Collection
Flow cytometry usually determines the CD4 count. The specimen is collected through a standard blood draw and undergoes processing within 18 hours of specimen collection.
Procedures
Laboratory measurement of CD4 count through flow cytometry is reported as CD4 percentages. The absolute CD4 count is obtained by multiplying this percentage with the total measured white blood cell (WBC) count. The absolute CD4 count usually corresponds to the CD4 percentages. A CD4 percentage of greater than 29% corresponds to an absolute count of more than 500 cells/microliters, 14% to 28% corresponds to an absolute count between 200 and 500 cells/microliters, and less than 14% corresponds to an absolute count of fewer than 200 cells/microliters. It is, however, important to note that an increase in WBC will cause an increase in the absolute CD4 count while the CD4 percentage remains the same. CD4 count measurements may also have inter-assay or inter-laboratory variability.[6][7][8]
Indications
CD4 count monitoring primarily serves to assess when to initiate prophylaxis against several opportunistic infections. While it is useful in monitoring response to ART, CD4 count is, by itself, insufficient in evaluating response to therapy. Viral load monitoring remains the most reliable indicator of treatment response.
The CD4 count is necessary at baseline and three months after the initiation of ART. It is subsequently monitored every 3 to 6 months during therapy. According to treatment guidelines, less frequent monitoring (every 12 months) may be sufficient after two years of ART in patients who have a stable CD4 count of greater than 300 cells/microliters and consistently undetectable viral load.
Potential Diagnosis
CD4 count, although an essential part of HIV management, is not primarily used for the diagnosis of HIV infection. However, an absolute CD4 count of fewer than 200 cells/microliter is one of the criteria utilized by the Center for Disease Control and Prevention (CDC) in the definition of AIDS. This clinical-stage indicates high susceptibility to opportunistic infections.
Normal and Critical Findings
The normal CD4 count range is between 500 and 1400 cells/microliters., taking into consideration laboratory variations.
Interfering Factors
There is significant intraindividual variability in CD4 count measurement. In a pre-ART (antiretroviral therapy) study, researchers found the intraindividual coefficient variation in 1020 untreated HIV patients to be at 25% on average. This variability was found even in healthy adult subjects. Several factors contribute to this variability. Any factors that lead to an increase or decrease in WBC count may cause changes to the measured absolute CD4 count. These factors include infection, medications, or other chronic conditions. Leukocytosis may increase the absolute CD4 count, while leukopenia may result in a decreased count. Patients with a history of splenectomy tend to have higher absolute CD4 cell counts, while patients with advanced liver disease and splenomegaly tend to have lower counts, which may be related to splenic sequestration. In these cases, the CD4 percentage usually has less variation. Therefore, any discordant changes between the absolute CD4 count and CD4 cell percentage should lead the clinician to investigate for possible factors that may be causing the changes, and caution should be used in CD4 count interpretation since it may not truly reflect the patient’s immunologic status.
Certain viral and bacterial infections have correlations with a mild decrease in CD4 cell count. These have been documented in viral infections such as Ebstein Barr Virus (EBV), cytomegalovirus (CMV), and HTLV-1 and bacterial infections such as tuberculosis. Patients with Hepatitis C virus (HCV) cirrhosis tend to have lower CD4 cell counts, and HIV patients with HCV co-infection seem to have reduced immune recovery upon initiation of antiretroviral therapy.[9][10] Medications such as corticosteroids may also affect WBC counts, which in turn lead to changes in CD4 cell counts.[11] Alcohol misuse also correlates with a drop in the absolute CD4 count.[12] A rare syndrome called idiopathic CD4 lymphocytopenia has been described, defined as a low CD4 count in the absence of HIV infection or any other medical conditions that may explain the disease.[13][14]
Clinical Significance
CD4 count depletion is a consequence of HIV infection and leads to devastating opportunistic infections when left untreated. It affects both CD4 helper T cells in the lymphoid tissue as well as T cells circulating in the peripheral blood. In the natural history of HIV infection, there is an abrupt decline in the CD4 count during acute HIV infection that is usually followed by a rebound as a result of CD8 lymphocyte response to viral replication. Without antiretroviral treatment, the CD4 count will then decline over the next several years.[15]
CD4 cell counts are used to monitor the immunologic response to ART. With effective viral suppression, CD4 count should increase by at least 50 cells/microliter after 4 to 8 weeks of treatment and by approximately 100 to 150 cells/microliters increase from baseline at one year. This phase is then followed by an expected increase of 50 to 100 cells/microliter per year. Several factors, such as older age, lower CD4 baseline, and severe immunocompromised status, have been associated with a less than expected improvement in the CD4 count while on treatment.[16][17]
CD4 count is not a reliable indicator of virologic suppression and medication adherence. In patients who develop virologic resistance while on ART, it may take months for the CD4 count to decline, and it may even initially increase. Several factors may falsely increase or decrease CD4 cell counts that may not necessarily reflect a patient’s actual immunologic status. Inter-laboratory variability must also merit consideration. Thus, any significant but unexpected difference between two CD4 count measurements, defined as a 30% change in absolute CD4 count or 3% change in CD4 percentage, must be confirmed with repeat testing.
References
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Disclosure: Raymund Li declares no relevant financial relationships with ineligible companies.
Disclosure: Doug Duffee declares no relevant financial relationships with ineligible companies.
Disclosure: Maryam Gbadamosi-Akindele declares no relevant financial relationships with ineligible companies.
- CD4+ cells recovery in HIV positive patients with severe immunosuppression at HAART initiation at Centre Medico-Social Cor-Unum, Kigali.[Pan Afr Med J. 2017]CD4+ cells recovery in HIV positive patients with severe immunosuppression at HAART initiation at Centre Medico-Social Cor-Unum, Kigali.Merci NM, Emerence U, Augustin N, Habtu M, Julie I, Angelique T, Jessica B, Cynthia A, Penda AT. Pan Afr Med J. 2017; 26:14. Epub 2017 Jan 12.
- Human T-cell leukemia virus type 1 (HTLV-1) p12I down-modulates ICAM-1 and -2 and reduces adherence of natural killer cells, thereby protecting HTLV-1-infected primary CD4+ T cells from autologous natural killer cell-mediated cytotoxicity despite the reduction of major histocompatibility complex class I molecules on infected cells.[J Virol. 2007]Human T-cell leukemia virus type 1 (HTLV-1) p12I down-modulates ICAM-1 and -2 and reduces adherence of natural killer cells, thereby protecting HTLV-1-infected primary CD4+ T cells from autologous natural killer cell-mediated cytotoxicity despite the reduction of major histocompatibility complex class I molecules on infected cells.Banerjee P, Feuer G, Barker E. J Virol. 2007 Sep; 81(18):9707-17. Epub 2007 Jul 3.
- Guidelines for the use of antiretroviral agents in HIV-infected adults and adolescents. Department of Health and Human Services and Henry J. Kaiser Family Foundation.[MMWR Recomm Rep. 1998]Guidelines for the use of antiretroviral agents in HIV-infected adults and adolescents. Department of Health and Human Services and Henry J. Kaiser Family Foundation.. MMWR Recomm Rep. 1998 Apr 24; 47(RR-5):43-82.
- Review [Deep lung--cellular reaction to HIV].[Rev Port Pneumol. 2007]Review [Deep lung--cellular reaction to HIV].Tavares Marques MA, Alves V, Duque V, Botelho MF. Rev Port Pneumol. 2007 Mar-Apr; 13(2):175-212.
- Review HIV infection and rheumatic diseases--autoimmune mechanisms in immunodeficient hosts.[Z Rheumatol. 1992]Review HIV infection and rheumatic diseases--autoimmune mechanisms in immunodeficient hosts.Weyand CM, Goronzy JJ. Z Rheumatol. 1992 Mar-Apr; 51(2):55-64.
- CD4 Count - StatPearlsCD4 Count - StatPearls
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