key: cord-0009286-xonek1g9 authors: Cubitt, W.D.; Mcswiggan, D.A. title: CALICIVIRUS GASTROENTERITIS IN NORTH WEST LONDON date: 1981-10-31 journal: Lancet DOI: 10.1016/s0140-6736(81)91167-3 sha: 07ea23dfe096a60cb5596f07dbe7bf0a6233f1f2 doc_id: 9286 cord_uid: xonek1g9 During a thirty-month study of gastroenteritis in North West London, 592 cases were found to be associated with excretion of viruses. 39 (6ยท6%) of these patients, most of whom were admitted to hospital because of gastroenteritis, were shedding caliciviruses. The cases occurred throughout the year with a peak incidence in the winter. The 39 patients ranged in age from 6 weeks to 13 years, the peak incidence beig among infants aged 1-6 months. The clinical features of calcivirus infection are not distinguishable from those of rotavirus infection. X-ray examination of the chest was performed in six of the children and aided the diagnosis in two cases. A skull X-ray was performed in only one instance and was not helpful. Negative radiological findings should not deter the clinician from screening relatives in an attempt to confirm the diagnosis of TBM. In our small series, definite contacts were identified by chest X-ray in four out of five cases. Three of the six children who had CAT scans had been referred initially to the neurosurgical unit to exclude spaceoccupying lesions. In five of these children the scan showed ventricular dilatation and was, therefore, helpful in diagnosis and management. Only one child was old enough to have had routine antituberculous screening at school, but, although the Heaf test was positive, the chest X-ray at the time was reported as normal. It is traditionally taught that there is a long history of illness in TBM, but some children, particularly younger ones, may have a much shorter history. 5, 8 Convulsions were the presenting feature in up to 20% of children under 2 years in one study,5 and one child in our series was admitted with convulsions associated with fever. Choroidal tubercles were not found in any of the seven cases, which is in agreement with the suggestion8 that choroidal tubercles are found in TBM only in association with miliary tuberculosis; none of the children in our series had miliary tuberculosis. Although local increases in the frequency of TBM do not necessarily reflect a national trend, we have shown that TBM still occurs in children in the U.K. and it is not confined to immigrant familes. The history may be short and convulsions are not uncommon. The use of the wrong tuberculin skin test may delay treatment, and a Mantoux 1:1000 test should be used whenever the diagnosis of TBM is in question. The diagnosis is not excluded by a normal chest X-ray. Contacts should be followed up energetically. A bromide partition test is an additional useful, safe, and easy test. Requests for reprints should be addressed to A. M. W., University Department of Paediatrics, John Radcliffe Hospital, Oxford OX3 9DU. During a thirty-month study of gastroenteritis in North West London, 592 cases were found to be associated with excretion of viruses. 39 (6·6%) of these patients, most of whom were admitted to hospital because of gastroenteritis, were shedding caliciviruses. The cases occurred throughout the year with a peak incidence in the winter. The 39 patients ranged in age from 6 weeks to 13 years, the peak incidence beig among infants aged 1-6 months. The clinical features of calcivirus infection are not distinguishable from those of rotavirus infection. INTRODUCTION WITHIN the past decade viruses have been demonstrated by electron microscopy in the stools of those with and those without the symptoms of gastroenteritis. The agents reported include rotavirus, Norwalk-like agents, calicivirus, astrovirus, and coronavirus. The aetiological role of most of these agents is still not clearly defined and further information on the part they play in human diarrhoea has been called for.' I This report presents some further clinical, serological, and epidemiological data on one of the more recently discovered agents, calicivirus, and is based on a study of 39 sporadic cases in North West London. Through the period January, 1979-June, 1981, samples of specimens of stools sent to the laboratory from patients with a history of gastroenteritis or diarrhoea and vomiting were examined by electron microscopy, whether or not such examination was requested. Most of these specimens had been found to be negative for bacterial pathogens (shigella, campylobacter, and salmonella); however, for some of the others we do not know whether pathogenic bacteria were present. The methods used for faecal examination and for immune electron microscopy (IEM) have been described elsewhere. 2 2 Identification was based on demonstration of the characteristic morphological features of the Caliciviridae.2,3 When calicivirus particles were detected in a specimen a questionnaire restricted to a small number of features, to be indicated as present or absent, was sent to the clinician with the report. The age and sex of the patient and month when the specimen was collected were obtained from the request forms as these data were regarded as reliable. During the period of the study, viruses were detected by electron microscopy-in the stools of 592 patients with gastroenteritis. 39 (6-6%) cases were associated with calicivirus excretion. (A separate report on other features of this study is being prepared.) Questionnaires were completed for 28 (72%) of the patients with calicivirus. The data presented are based on these responses except in respect of age and sex of patient and month of infection, which are based on 39 cases. OUTBREAK STRAINS OF CALICIVIRUS was reported in a third of the cases.9 Failure to thrive and malabsorption was reported in only 3 cases. 5 children had fever. The duration of symptoms ranged from two to eleven days with most illnesses lasting about four days. 13 (46%) of the affected children had siblings and, of these, 5 had at least 1 sibling with similar symptoms of illness. In 1 case the brother attended a school where there was a concurrent outbreak of diarrhoea and vomiting. The duration of excretion of viruses is shown in table I; the finding that the chances of detecting virus diminishes after the fourth day emphasises the need to obtain specimens during the symptomatic phase of illness."5 Serology (immune electron microscopy [IEM] .-Four strains of virus found in sporadic infections were tested against sera from three reported outbreaks2,4,6 (table II). There is little evidence of serological relations between the sporadic strains and strains associated with two of the outbreaks, but there is some evidence for a relation with the third.2 DISCUSSION Viruses morphologically identical with caliciviruses have recently been detected in animals',8 and people9-1 with gastroenteritis. The study of outbreaks in man in the U.K.,2,4,12 Japan,6 and Canadal3 has provided evidence that these viruses can cause diarrhoea and vomiting in all agegroups other than neonates. The apparent absence of cases in neonates may be due to predominantly asymptomatic infection or be associated with immunity due to maternal antibody. In the series of sporadic cases reported here, diarrhoea was the most frequent symptom, whereas, in children aged four to six years, vomiting was more common.2 It has been suggested5 that these differences in symptoms may be agerelated. However, since vomiting has been reported as the commonest feature in infected infants aged nine days to two years, age does not appear to be the sole determinant. 13 Other clinical features, such as fever and upper respiratory tract infection, have been reported infrequently. Thus the clinical features of calicivirus gastroenteritis are not distinguishable from those due to rotavirus infection. Several cases of calicivirus infection associated with failure to thrive have led us to consider the possibility of an aetiological relation. However, the results of this small survey do not provide much support for this view. Diarrhoea developed ten or more days after admission to hospital in 3 out of 26 infants, indicating that caliciviruses, like rotaviruses, can be a cause of nosocomial infection. Little is known about the range of human calicivirus serotypes. Results from this and a previous study4 provide evidence for at least three distinct serotypes which have been associated with outbreaks. The limited data obtained on the sporadic cases from North West London suggest that they may be associated with strains from one of these outbreaks.2 Whether strain differences, as reflected by IEM serology, have any implications for susceptibility to repeated infection with calicivirus or are, in any way, related to geographical distribution, remains to be established. Caliciviruses have been identified as a cause of gastroenteritis only in countries where electron microscopy facilities are readily available. Surveys of viral gastroenteritis in these areas indicate that calicivirus accounts for a proportion of gastroenteritis cases (Japan 2%,'° Scandinavia 5%,' and U.K [present study] 6' 6%). Caliciviruses OPPORTUNITIES for specialist physicians wishing to work in tropical developing countries have diminished in recent years. It is still possible to obtain a post in Papua New Guinea, although the positions available now will be filled within the next few years by local graduates. Surprisingly little is known in Europe about the country,* and it is difficult to obtain accurate information about existing work. The work of junior medical officers in Papua New Guinea has, however, been the topic of several recent articles. 1,2 The central highlands are mostly above 5000 feet, and although just south of the equator, the climate is mild with cool nights. As a result, malaria is not prevalent, and the valleys are densely populated; deforestation is accordingly extensive. The coastal regions of the mainland, however, and the large islands to the north and east (Manus, New Ireland, New Britain, and Bougainville) are hot and humid throughout the'year; malaria is endemic and population densities are relatively low. The Highlands Highway, which runs from Lae on the coast to Mount Hagen and beyond, is not completely sealed, and poor driving standards together with alcohol abuse contribute to a high rate of motoring accidents.3 In 1979, P.N.G. had 67 deaths per 10 000 registered vehicles.4 4 Communication between Port Moresby and the rest of the country and the outlying islands is by air or sea, although travel by air is expensive. *P N G. is 178 260 square nules in area, and the populanon is esumated to be 3 168 700 The Health Services The health services of P.N.G. are comprehensive and well organised. The Health Department has base hospitals at Port Moresby, Lae, Goroka, Madang, and Rabaul. Port Moresby General Hospital has four general medical units, two of which are directed by university physicians, while the other base hospitals have one physician, surgeon, paediatrician, and obstetrician. Anaesthetics are usually administered by specially trained nurses or resident medical officers. Within the region served by a base hospital are a number of district hospitals staffed by general medical officers (often expatriate) and nurses. The district hospitals in turn provide a referral centre for the health centres in outlying areas, which are manned by health extension officers (H.E.O.s), paramedical workers who have completed a 3-year course in basic medicine. The health centres supervise a number of aid posts which are in the charge of aid post orderlies (A.P.O.s), competent to treat minor maladies and common illnesses such as malaria. This system provides basic medical care for every person, even in remote areas. The University of Papua New Guinea is situated in Port Moresby. There are three posts for consultant physicians in clinical medicine, one chair and two senior lectureships, one of which is at Goroka. The Papua New Guinea Institute of Medical Research is Tuberculous meningitis in children Tuberculous meningitis The diagnosis of tuberculous meningitis Reason for variable response to the tine test Tuberculous meningitis in children Treatment of tuberculous meningitis The blood-CSF barrier to bromide in the diagnosis of tuberculous meningitis The early diagnosis of tuberculous meningitis Report of the Sub-group of the Scientific Working Group on Epidemiology and Etiology: Rotavirus and other viral diarrhoeas Winter vomiting disease caused by calicivirus A model for vesicular exanthema virus. The prototype of the calicivirus group A new serotype of calicivirus associated with an outbreak of gastroenteritis in a residential home for the elderly Faecal shedding of virus in relation to the days of illness in infantile gastroenteritis due to calicivirus An outbreak of gastroenteritis associated with calicivirus in an infant home Isolation of small viruses resembling astroviruses and caliciviruses from acute enteritis in calves Rotavirus-like, calicivirus-like, and 23 mm virus-like particles associated with diarrhoea in young pigs Stool viruses in babies in Glasgow Caliciviruses in man The occurrence of calicivirus in infants with acute gastroenteritis An outbreak of calicivirus infection in a mother and baby unit Nosocomial infantile gastroenteritis associated with minirotavirus and calicivirus Small spherical viruses in faeces from gastroenteritis patients