Human T cell leukaemia/lymphoma virus infection in pregnant women in the United Kingdom: population study

doi:10.1136/bmj.320.7248.1497

BMJ 2000;320:1497-1501 ( 3 June )

Papers

Human T cell leukaemia/lymphoma virus infection in pregnant women in the United Kingdom: population study

A E Ades, reader ^a, Simon Parker, research assistant ^b, Jane Walker, computer programmer ^a, Mark Edginton, research technician ^b, Graham P Taylor, lecturer ^c, Jonathan N Weber, professor ^c.

^a Department of Epidemiology and Public Health, Institute of Child Health, London WC1N 1EH, ^b Department of Virology, Great Ormond Street Children's Hospital NHS Trust, London WC1N 3JH, ^c Department of Genitourinary Medicine and Communicable Diseases, Imperial College School of Medicine, St Mary's Hospital, London W2 1PG

Correspondence to: A E Ades a.ades{at}ich.ucl.ac.uk

Abstract

Top
Abstract
Introduction
Methods
Results
Discussion
References

Objective: To assess the prevalence of human T cell leukaemia/lymphomavirus (HTLV) infection in pregnant women in the UnitedKingdom.
Design: Populationstudy.
Subjects: Guthrie card samples from babies born in 1997-8.Samples were linked to data on mother's age and ethnic statusand parents' country of birth and thenanonymised.
Setting: North Thames Regional HealthAuthority.
Main outcome measures: Presence of antibodies against HTLV in eluatestested by gelatin particle agglutination assay and results confirmedbyimmunoblot.
Results: Of 126 010 samples tested, 67 had confirmedantibodies to HTLV (59 HTLV-I, 2 HTLV-II, 6 untyped) and six hadindeterminate results. Seroprevalence was 17.0 per 1000 (95% confidenceinterval 9.2 to 28.3) in infants whose mothers were born in theCaribbean, 3.2/1000 (1.5 to 5.9) with mothers born in west andcentral Africa, and 6.8/1000 (3.1 to 12.9) in infants of blackCaribbean mothers born in non-endemic regions. In infants withno known risk (both parents born in non-endemic regions and mothernot black Caribbean) seroprevalence was 0.06-0.12 per 1000. Mother'scountry of birth, father's country of birth, and mother's ethnicstatus were all independently associated with neonatal seroprevalence.An estimated 223 (95% confidence interval 110 to 350) of the 720000 pregnant women each year in the United Kingdom are infectedwithHTLV.
Conclusions: The prevalence of HTLV and HIV infectionsin pregnant women in the United Kingdom are comparable. The costeffectiveness of antenatal HTLV screening should be evaluated,and screening of blood donations should beconsidered.

Introduction

Top
Abstract
Introduction
Methods
Results
Discussion
References

Human T cell leukaemia/lymphoma virus type I (HTLV-I) is endemic in the Caribbean, Japan, South America, west and centralAfrica, and isolated pockets elsewhere. It is causally associatedwith adult T cell leukaemia/lymphoma and HTLV-I associated myelopathyand tropical spastic paraparesis.¹ The association of HTLV-IIwith neurological and lymphoproliferative disorders is less certain.²HTLV-II is endemic in some Amerindian groups and in parts of Africa.¹The epidemiology of HTLV in Europe and worldwide has been reviewedrecently. ³ ⁴ Phylogenetic trees based on nucleotide sequencinghave thrown further light on the worldwide distribution of HTLVand its origin in simian T cell lymphoma/leukaemia viruses. ² ⁵ ⁶

Both types of HTLV can be transmitted through breast feeding, sexual contact, and blood transfusion and percutaneously. ¹ ⁷ A high prevalence of HTLV, particularly HTLV-II, has been recordedamong injecting drug users in the United States⁸ and partsof Europe.³ Blood donors are routinely screened for HTLV inJapan, the United States, Canada, France, the French West Indies,Portugal, Sweden, the Netherlands, Denmark, andFinland.

Rates of transmission from mother to child are 2.7% in formula fed infants, 5% with three months' breast feeding, and up to20% with prolonged breast feeding.^9-11 Vertically acquired HTLV-Ileads to adult T cell leukaemia/lymphoma in 1-5% of infected infants.⁷Antenatal screening for HTLV, to recommend formula feeding, hasbeen carried out in the Nagasaki prefecture of Japan since 1987¹²and has been proposed in Europe ^13-17 and Jamaica.¹⁸

In the United Kingdom, studies of HTLV seroprevalence in pregnant women have been small, local, and confined to multiethnicinner city areas. ¹³ ¹⁴ ¹⁶ ^19-21 This study, based on the presenceof HTLV specific antibody in neonates, which is a reliable markerof maternal infection, examines the wider seroepidemiology ofHTLV in the North Thames region of south east England. This includesinner London, suburban, and remote rural districts. From thiswe derive estimates of antenatal seroprevalence in the UnitedKingdom as a whole and discuss the implications for both antenataland blood donorscreening.

Methods

Top
Abstract
Introduction
Methods
Results
Discussion
References

Population and sources of demographic data
The study included all the 126 010 non-repeatGuthrie card samples arriving over 15 months in 1997-8 in theNorth Thames neonatal screening laboratory, which serves almost15% of newborn babies in the United Kingdom. Over the last 12months of the study, demographic data were linked to samples beforeirreversible unlinking and testing, as described elsewhere.²²Parents' country of birth, recorded at civil registration of births,was obtained from the Office for National Statistics. Maternalethnic status and age at delivery was available from child healthcomputers in 14 of the 29 districts in the study. Ethical approvalwas obtained from local committees covering the studypopulation.

Serology
Two 4.9 mm dried blood spot samples were punchedinto flat bottomed microtitre plates and eluted overnight at 4°Cin 170 µl of eluate buffer.²³ Eluates were screened by a modifiedanti-HTLV gelatin particle agglutination assay, which has beenshown to be sensitive to anti-HTLV in simulated dried blood spotsamples from patients with HTLV-1 from the United Kingdom, SouthAfrica, and Japan.²⁴ Tests on serial dilutions of a panel of23 samples from the HTLV European Research Network showed reliabledetection of anti-HTLV-I and anti-HTLV-II in dried blood spoteluates derived from serum samples with titres as low as 1:50.Repeat reactive samples were confirmed and typed by immunoblotting(HLTV blot 2.4, Genelabs Diagnostics, Singapore) at a dilutionof 1:50 and according to manufacturer'sinstructions.

Statistical methods
We used SAS PROC GENMOD for binomial datato perform multivariate analyses with profile likelihood confidenceintervals. Additive risk regression was used to assess the effectof parents' region of birth and mother's ethnic status,²⁵ andlogistic regression was used elsewhere. Single proportions werecompared by Fisher's exact test. We estimated the prevalence ofmaternal HTLV infection in the United Kingdom by multiplying groupspecific risks derived from this study and published data intogroup population sizes estimated from routine birth registrationand 1991 censusstatistics.

Results

Top
Abstract
Introduction
Methods
Results
Discussion
References

Serology and status of indeterminate samples
Of the 126 010 samples tested, 85 were reactiveon first gelatin particle agglutination assay and 75 on repeattesting. All 10 samples that were non-reactive on repeat testinggave negative results on immunoblotting. Sixty seven of the 75repeat reactive samples were confirmed as seropositive (59 HTLV-I,2 HTLV-II, and 6 HTLV untyped), six were indeterminate, and twowere negative. The figure shows the HTLV titres of all 85 initiallyreactive samples. Six (7%) samples had titres of 1 in 5, the lowestcategory above the detection limit, suggesting a false negativerate of no more than 2-3%.

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Table 1. Risk factor distribution of infants with confirmed anti-HTLV positive, indeterminate, and negative eluates. Percentages are given for samples for which presence or absence of risk factors could be determined

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Table 2. Maternal prevalence of HTLV infection per 1000 including samples with indeterminate results, by mother's country of birth

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Gelatin particle agglutination titres of reactive eluates

Table 1 compares the demographic features of the babies with indeterminate samples with those of babies with confirmed seropositiveand seronegative results. Among those with known risk status,only 18% (7558/41 487) of babies with negative results had riskfactors for infection compared with 37/39 (95%) of those withconfirmed positive results (P<0.0001). Two out of four babieswith indeterminate samples had a known risk factor. This proportionwas not significantly different from that of babies with negativesamples (P=0.15) but significantly lower than in those with confirmedpositive samples (P=0.037). In view of the uncertain status ofthe six indeterminate samples, we assumed for seroprevalence estimatesthat half the six indeterminate results were HTLV positive. Confidenceintervals incorporate thisuncertainty.

Seroprevalence in relation to demographic factors
Maternal prevalence of HTLV infection washighest in Caribbean born women, 16.9 (95% confidence interval9.2 to 28.3) per 1000. Prevalence in women born in western orcentral Africa was 3.2 (1.5 to 5.9) per 1000. Prevalence was alsohigh in mothers born in Japan and in South America (table 2).These endemic areas accounted for 51% of maternal infection. Theremaining 49% of infected mothers were born in Europe, where seroprevalencewas 0.36 (0.21 to 0.55) per 1000. The distribution of infectionacross father's country of birth was verysimilar.

Maternal ethnic status was known in 40 868 cases. In the 29 confirmed and indeterminate cases where ethnic status was known,15 (52%) mothers were black Caribbean, five (17%) black African,and six (21%) white. There were no cases of HTLV in babies bornto the 7495 mothers recorded as Asian or to 571 British born blackAfrican women, but there were four confirmed positives cases andtwo indeterminate among 26 905 babies born to whitewomen.

Among 32 985 infants with no known risk factors (both parents born in non-endemic areas, mother not black Caribbean) therewere two positive and two indeterminate samples (prevalence 0.06-0.12per 1000). Among infants with a non-black mother born in a non-endemicarea, whose only risk was therefore father's country of birth,seroprevalence was 0/352 if the father was born in an endemicarea but 2/2347 when the father's country of birth wasunknown.

In an analysis of parental country of birth and mother's ethnic status as risk factors for neonatal seropositivity, an additiverisk model fitted better ( $chi$ ²=32.6,df=38, P=0.7) than a logistic regression model ( $chi$ ²=56.3, df=38, P=0.028) and gave no significant interactions.Table 3 gives the additional risk of being seropositive conferredby each risk factor, relative to a baseline group of infants withseroprevalence 0.098 per 1000 with no parental risk indicators.

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Table 3. Additive binomial regression estimates of the contribution of parents' region of birth and mother's ethnic status on neonatal seroprevalence for HTLV. Central estimates are the average, and confidence limits the most extreme, of those obtained including or excluding indeterminate results as seropositive

Anti-HTLV was rare in infants with mothers under 26 years old (table 4), and prevalence increased greatly with maternal ageamong all groups at risk of HTLV infection ( $chi$ ² =12.6, df=1, P=0.0004). Prevalence was higher in women born inthe Caribbean than black Caribbean women born in non-endemic areas(relative risk 2.9, 95% confidence interval 1.2 to 7.1). Thiseffect was not significant after age was controlled for, but thedata remained consistent with a substantial excess risk (relativerisk 1.9, 0.8 to 4.9).

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Table 4. Seroprevalence of HTLV per 1000, by mother's age for babies whose mother's country of birth was also known. Samples with indeterminate results (shown in parentheses) are included in seroprevalence estimates

Seroprevalence increased from non-metropolitan districts, through outer London, to inner London (table 5). However, thisgeographical variation can be attributed to distribution of therisk groups. Using only samples for which the presence or absenceof risk group was known, we found that the significant trend ( $chi$ ²=11.6, df=1, P=0.0007) was eliminated after risk group was controlledfor ( $chi$ ²=0.4, df=1, P=0.5). In inner London, an estimated 90% (22/24.5)of seropositive samples occurred in babies with a maternal riskfactor compared with 92% (11/12) in outer London and 57% (2/3.5)in non-metropolitan areas.

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Table 5. HTLV seroprevalence per 1000 births by risk group and type of district of birth for samples with known district of birth. Seroprevalence is an average of minimum and maximum estimates

Overall prevalence among pregnant women in United Kingdom
To project our seroprevalence findings acrossthe whole of the United Kingdom we multiplied risk group specificprevalence estimates from this study and elsewhere into populationestimates (table 6). We assumed that seroprevalence is homogeneouswithin groups across the country. This assumption is supportedby the preceding analysis for North Thames (table 5), althoughwe stratified the low risk into two groups. The overall numberof pregnant women in the United Kingdom infected each year withHTLV is predicted to be 223 (95% confidence interval 113 to 347)out of a total 720 000, representing an overall prevalence of0.31 per 1000 (0.16 to 0.48). The main source of uncertainty isthe small numerator in the majority (lowest risk) group, whichmay account for between 6% and 58% of maternal infection.

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Table 6. Estimates of number of pregnancies in United Kingdom each year in which mother is infected with HTLV. Central estimates are an average and confidence limits the most extreme of those obtained including and excluding indeterminate results as seropositive

	Discussion

Top Abstract Introduction Methods Results Discussion References

Our results agree well with what is known about the endemicity of HTLV in the Caribbean, west and central Africa, and elsewhere. ¹ ³ The rapid increase in seroprevalence with age and the low seroprevalencein the youngest groups (table 4) point to sexual contact as theprimary mode of transmission among women of child bearing age,with only a small fraction attributable to breast feeding. Thisis also consistent with reports from Africa, Jamaica, and SouthAmerica.^31-33 The finding of 1.1 per 1000 seroprevalence in innerLondon is comparable with estimates of 1.4 to 3.9 per 1000 fromsmaller studies set in similar areas. ¹³ ¹⁴ ¹⁶ ^19-21

The precise prevalence of HTLV-II remains in doubt. Anti-HTLV-II was detected in two of the 126 010 samples (0.016 per 1000).However, untyped anti-HTLV positive results are more frequentin samples from Africa than from the Caribbean (table 1), andone or more of the three untyped African samples may be HTLV-II.The gelatin particle agglutination assay is equally sensitiveto anti-HTLV-I and anti-HTLV-II.³⁴ However, the serum antibodytitre of patients with HTLV-II may be lower than that of patientswith HTLV-I,³⁵ and therefore more eluates may have fallen belowthe detection limit. On the other hand, the 59:2 ratio of HTLV-Ito HTLV-II recorded here is similar to the 32:1 reported in arecent study based on serum samples in London.²¹

Screening implications
Several investigators have urged that antenatalscreening for HTLV be considered in the United Kingdom in orderto prevent vertical transmission of HTLV through breast feeding.The 233 a year nationwide antenatal prevalence of HTLV predictedin this study is comparable to the recent 330 a year estimatefor HIV.³⁶ Furthermore, the estimated prevalence of HTLV of0.06-0.12 per 1000 births among those with no known risk factorsin North Thames compares with the prevalence of HIV of 0.10 per1000 births among United Kingdom born women with United Kingdomborn partners reported in the same region.²²

The United Kingdom has recently joined many other countries in recommending universal antenatal testing for HIV,³⁷ but thearguments for antenatal HTLV testing may be less compelling. AlthoughHTLV may be transmitted to 20% of children breast fed for a prolongedperiod, the transmission rate is only 5% with three months' breastfeeding.^9-11 In Britain 34% of mothers do not breast feed at all,and only 35% breast feed for over 3 months.³⁸ Breast feedingmay be more prolonged among women born in endemic areas, but thesewomen account for only 32% of prevalent cases (table 6). Therate of vertical transmission of HTLV in the United Kingdom istherefore likely to be under 10% (22/223), which could be reducedto 2.7% (6/223) by formula feeding.⁹ Not only is the burdenof preventable infection therefore quite low, but the lifetimerisks of HTLV related disease are also small: 1-5% for adult Tcell leukaemia/lymphoma,⁷ and 0.25-3% for HTLV-1 associatedmyelopathy and tropical spastic paraparesis. ¹ ³⁹ Maternalinfection may therefore lead to disease in only 0.1% to 1% ofoffspring.

The potentially negative impact of a maternal diagnosis of HTLV on the family's quality of life is a further critical factor,as between 10 and 20 infected women would need to be diagnosedto prevent one paediatric infection, and no effective treatmentsexist for HTLV infection or HTLV related diseases. A thorougheconomic evaluation would establish whether there is a net benefitto diagnosing an HTLV infected pregnant woman. If there is a benefit,our findings suggest that targeting high risk women or universaltesting in high prevalence areas could identify most women infectedwith HTLV at relatively lowcost.

The conjecture that HTLV may be as frequent in the general United Kingdom population as HIV also has implications for blooddonor screening. The prevalence of HTLV infection in women withno risk factors and low risk partners of 0.06-0.12 per 1000 birthscompares with the 0.05/1000 (5/96 720) prevalence reported inblood donors in north London in 1993⁴⁰ and 0.014 /1000 (1/76452) in the north of England.⁴¹ The prevalence of HIV nationallyin 1998 was 0.04/1000 in eligible first time blood donations and0.004/1000 in repeat donations.⁴² Although the risks of infectionand disease after contaminated transfusion are less with HTLVthan with HIV, ⁴³ ⁴⁴ screening first time donors for HTLV wouldnot be inconsistent with the present policy of screening all donationsfor HIV.

What is already known on this topic

Human T cell leukaemia/lymphoma virus (HTLV) type 1 is associated with adult T cell leukaemia and progressive neurological disease; HTLV-II is less common in the United Kingdom but is also associated with serious disease

The viruses can be transmitted sexually, percutaneously, and from mother to child

Antenatal screening is carried out in Japan and many countries screen blood donations for HTLV

What this study adds

The prevalence of HTLV among pregnant women in the United Kingdom is estimated to be 0.31 per 1000, similar to the prevalence of HIV

In inner city areas about 90% of HTLV is associated with birth or ethnic origin in endemic areas, compared to 50% in non-metropolitan areas.

Antenatal HTLV testing is likely to be less beneficial economically and clinically than antenatal HIV testing but should be fully evaluated

Screening of blood donations should be considered

	Acknowledgments

Contributors: AEA conceptualised the study and analyses, drafted the paper, and is the guarantor. ME carried out the laboratory work supervised by SP. JW carried out all data processing including data linkage and anonymisation. The study is part of the HTLV European Research Network International Antenatal Seroprevalence Study (HERNIAS) Concerted Action, which is coordinated by GPT and JNW. All authors contributed to the paper.

Footnotes

Funding: European Community Biomed Programme, Contract BMH4 CT97-2710.

Competing interests: Nonedeclared.

References

Top
Abstract
Introduction
Methods
Results
Discussion
References

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(Accepted 23 February 2000)

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1.	Kaplan JE, Khabbaz RF. The epidemiology of human T-lymphotropic virus types I and II. Rev Med Virol 1993; 3: 137-148.
2.	Hall WW, Ishak R, Zhu SW, Novoa P, Eiraku N, Hidehiro T, et al. Human T lymphotropic virus II (HTLV-II): epidemiology, molecular properties and clinical features of infection. J AIDS 1996; 13(suppl 1): S204-S214.
3.	Taylor GP. The epidemiology of HTLV-I in Europe. J AIDS 1996; 13(suppl 1): S8-14.
4.	Taylor GP, McClure MO. Human oncoretroviruses. In: Arrand JR, Harper DR, eds. . Viruses and human cancer. Oxford: Bios Scientific, 1998:109-142.
5.	Gessain A, Rahieux R, de Thé G. Genetic variability and molecular epidemiology of human and simian T cell leukemia/lymphoma virus type I. J AIDS 1996; 13(suppl 1): S132-S145.
6.	Yamashita M, Ido E, Miura T, Hayami M. Molecular epidemiology of HTLV-I in the world. J AIDS 1996; 13(suppl 1): S124-S131.
7.	International Agency for Research on Cancer. Monographs on the evaluation of carcinogenic risk to humans. , Vol 67. Human immunodeficiency viruses and human T-cell lymphatropic viruses Lyons: IARC, 1996.
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