LETTERS
Can clinical algorithms deliver an accurate diagnosis of HIV infection in infancy?
Stephanie A. JonesI,1; Gayle G. ShermanII; Ashraf H. CoovadiaIII
IMedical Officer, Wits Paediatric HIV Working Group, PO Box 2086, Fourways, Johannesburg 2055, South Africa (email: stephanie.jones@hivsa.com)
IIAssociate Professor, Department of Molecular Medicine & Heamatology, University of the Witwatersrand and National Health Laboratory Services, Johannesburg, South Africa
IIIPaediatrician, Coronation Hospital, Wits Paediatric HIV Working Group, Johannesburg, South Africa
Editor The Integrated Management of Childhood Illness (IMCI) guidelines established clinical criteria to identify children with suspected HIV infection for HIV testing and specific management. In an article published in the Bulletin, based on a study conducted in South Africa, Horwood et al. report that they have fine-tuned these criteria into a clinical algorithm (1). This algorithm has been incorporated into the 2003 edition of the South African IMCI guidelines to maximize identification of HIV infected children (1, 2). Horwood et al.'s study clinically assessed 690 hospital outpatients, aged 259 months, in an HIV prevalence setting of 28.7%. In the absence of screening questions, the clinical algorithm was applied and yielded a sensitivity of 70%, specificity of 80% and a positive predictive value (PPV) of 59%. The validity of the algorithm for the 226 infants (211 months), 38% of whom were infected, did not to differ from that for the other age categories (1).Validation of the clinical algorithm in different settings was invited (1).
Vertically exposed infants in prevention-of-mother-to-child transmission (PMTCT) programmes in low-resource settings rely on clinical assessments for HIV diagnosis since infants are first tested at 12 months of age using an HIV enzyme-linked immunosorbent assay (ELISA). The HIV prevalence among infants will vary according to the availability of PMTCT services and the mode of infant feeding. We carried out a study to establish an affordable and accurate diagnostic protocol for HIV using a cohort of 301 infants attending a PMTCT clinic at Coronation Women and Children's Hospital, a secondary- level hospital in Johannesburg, South Africa (3). At 12 months of age, the infant's true HIV-infection status was determined using polymerase chain reaction testing according to the Centers for Disease Control and Prevention guidelines, in conjunction with clinical assessments (4). In a predominantly exclusively formula-fed population, 26 patients (8.7%) were HIV positive (3). At the visits at 6 weeks and at 3, 7 and 12 months of age, 18 different doctors experienced in local paediatric HIV care and blinded to the HIV test results prospectively diagnosed the infant's HIV infection status based on clinical findings. Two-thirds of all clinical examinations were performed by paediatricians. The clinical findings were recorded on a structured data collection tool that concentrated on clinical features derived from Center for Disease Control (CDC) clinical guidelines (i.e., recurrent infections, weight gain, candidiasis, lymphadenopathy, hepatosplenomegaly) (4). The number of HIV-infected infants who were correctly clinically diagnosed in our study increased with age from 56% at 6 weeks of age to 93% at 12 months of age.
The performance of the IMCI algorithm in our study population was retrospectively assessed by applying our source data to the South African 2003 IMCI clinical algorithm which consists of asking, looking and feeling for eight features of symptomatic HIV without the screening questions (5).
The disturbing finding was that the algorithm would have detected only 17% of HIV-infected infants at 6 weeks of age. Even though the detection rate improved to 50% for infants aged 12 months, this was still much lower than the rate of 70 % reported by Horwood et al. (1). Retrospective application of the IMCI algorithm to clinical data collected by highly skilled personnel therefore yielded particularly poor sensitivity in detecting HIV infection throughout infancy.
A long-term prospective study in Rwanda has documented that HIV-infected children in Africa develop early morbidity and mortality (6). In our cohort, all 15 surviving HIV-infected infants available for assessment at 12 months of age were symptomatic and required specific medical interventions, e.g. antifungal treatment for oral thrush. Despite this clinical scenario, eight (53%) of the 12-month-olds would not have been detected by the IMCI algorithm. The high early mortality rate of HIV-infected infants is a further concern, particularly with the increasing availability of antiretroviral therapy. Of the 10 HIV-infected infants who died before their first birthday, 5 (50%) would have remained undiagnosed by the IMCI algorithm. The clinical assessments in our study missed 2 (20%) of these children. Like Horwood et al., we noted that the higher sensitivity of the doctors' clinical assessments was often attributable to the detection of hepatosplenomegaly, which is not included in the IMCI algorithm (1).
Clinical diagnosis of HIV infection in infancy remains a challenge. Additional prospective assessments of the IMCI clinical algorithm in vertically exposed infants in PMTCT settings with different HIV prevalence are required. It is a cause for concern that in our PMTCT setting the IMCI algorithm used by highly skilled clinical practitioners only identified approximately half of the infants experiencing HIV-related mortality and morbidity at 12 months of age. In an era of expanding antiretroviral scale-up programmes, clinical assessment remains an unacceptably insensitive diagnostic tool for ensuring that HIV-infected infants access care. A more pragmatic approach may be to invest in assessment of affordable, simple methods of testing for early diagnosis of infants rather than relying on clinical skills alone. 
Competing interests: none declared.
References
1. Horwood C, Liebeschuetz S, Blaauw D, Cassol S, Qazi S. Diagnosis of paediatric HIV infection in a primary health care setting with a clinical algorithm. Bulletin of the World Health Organization 2003;81:858-66
2. World Health Organization, Regional Office for Africa. Report on the Workshop on Adaptation of IMCI Guidelines to include HIV/AIDS. Harare 18-23 June 2001.Available from: www.who.int/child-adolescenthealth/New_Publications/ HIV/report_HIV_Harare.htm (accessed 26 August 2004)
3. Sherman GG, Jones SA, Coovadia AH, Urban MF, Bolton KD. PMTCT from research to reality results from a routine service. South African Medical Journal 2004;94:289-92.
4. Centers for Disease Control. 1994 revised classification system for human immunodeficiency virus infection in children less than 13 years of age. Morbidity and Mortality Weekly Report 1994;(No. RR-12):1-10.
5. Integrated Management of Childhood Illness. South African Edition. South African Department of Health, Pretoria, South Africa. October 2003.
6. Spira R, Lepage P, Msellati P, Van der Perre P, Leroy V, Simonon A, et al. Natural history of human immunodeficiency virus type 1 infection in children: a five-year prospective study in Rwanda. Pediatrics 1999;104:e56.
1 Correspondence should be sent to this author.