ERYTHROCYTE SEDIMENTATION-RATE, WHITE BLOOD-CELL COUNT AND SERUM C-REACTIVE PROTEIN IN ASSESSING ETIOLOGIC DIAGNOSIS OF ACUTE LOWER RESPIRATORY-INFECTIONS IN CHILDREN

被引:67
作者
NOHYNEK, H
VALKEILA, E
LEINONEN, M
ESKOLA, J
机构
[1] HELSINKI UNIV, CTR COMP, HELSINKI, FINLAND
[2] AURORA HOSP, HELSINKI, FINLAND
来源
PEDIATRIC INFECTIOUS DISEASE JOURNAL | 1995年 / 14卷 / 06期
关键词
C-REACTIVE PROTEIN; ERYTHROCYTE SEDIMENTATION RATE; WHITE BLOOD CELL COUNT; ETIOLOGIC DIAGNOSTICS; ACUTE LOWER RESPIRATORY INFECTION;
D O I
10.1097/00006454-199506000-00004
中图分类号
R392 [医学免疫学]; Q939.91 [免疫学];
学科分类号
100102 ;
摘要
The clinical signs, symptoms and host responses (erythrocyte sedimentation rate, white blood cell count and C-reactive protein) were studied to distinguish bacterial from viral acute lower respiratory infection (ALRI) in 121 children hospitalized for ALRI. Etiologic diagnosis was based on blood culture, antibody assays and antigen detection, Children with bacterial involvement only were older than those with viral involvement alone (mean, 5.1 vs. 2.5 years), and their duration of respiratory symptoms had lasted longer (mean, 4.6 vs, 3.3 days). Children with unknown etiology had a shorter duration of fever before hospitalization than those with etiology identified with the methods used (mean, 1.6 vs. 2.9 days). The host response ranged widely within etiologic groups. The mean erythrocyte sedimentation rate did not differ significantly between the bacterial and viral ALRI (38 vs. 28 mm/hour); neither did white blood cell count (13.2 vs. 13.6 x 10(9)/liter) or C-reactive protein (68 vs. 49 mg/liter). No combination of clinical signs and host responses or any cutoff values could be shown to differentiate reliably bacterial from viral ALRI.
引用
收藏
页码:484 / 490
页数:7
相关论文
共 28 条
  • [1] Case management of ARI in children in developing countries: Report of a working group meeting, (1984)
  • [2] Acute respiratory infections in children: Case management in small hospitals in developing countries, A manual for doctors and other senior health workers, (1990)
  • [3] Ort S., Ryan J.L., Barden G., D'Esopo N., Pneumococcal pneumonia in hospital patients: Clinical and radiological presentations, JAMA, 249, pp. 214-218, (1983)
  • [4] Evans H.E., Infections of the lower respiratory tract in infancy and early childhood, Respiratory infections: Diagnosis and management, pp. 229-255, (1994)
  • [5] Mertsola J., Ziegler T., Ruuskanen O., Vanto T., Koivikko A., Halonen P., Recurrent wheezy bronchitis and viral respiratory infections, Arch Dis Child, 66, pp. 124-129, (1991)
  • [6] Halonen P., Obert G., Hierholzer J.C., Direct detection of viral antigens in respiratory infections by immunoassays: A four year experience and new development, Medical virology IV, pp. 65-85, (1985)
  • [7] Jalonen E., Paton J.C., Koskela M., Kerttula Y., Leinonen M., Measurement of antibody responses to pneumolysin: A promising method for the presumptive etiological diagnosis of pneumococcal pneumonia, J Infect, 19, pp. 127-134, (1989)
  • [8] Leinonen M., Luotonen J., Herva E., Valkonen K., Makela P.H., Preliminary serologic evidence for a pathogenic role of íiran-hanwlla catarrhalis, J Infect Dis, 144, pp. 570-574, (1981)
  • [9] Kleemola S.R.M., Karjalainen J.E., Raty R.K.H., Rapid diagnosis of Mycoplasma pneumoniae infection: Clinical evaluation of a commercial probe test, J Infect Dis, 162, pp. 70-75, (1990)
  • [10] Antibiotics in the treatment of acute respiratory infections in young children, Document WHü/ARI/90.10, (1990)
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