Background and Objective: Respiratory tract infection and allergy are common illnesses in children. Pneumonia and asthma are diseases involving lower respiratory tract and contributing to mortality and morbidity in children. Evidences have shown that respiratory diseases are closely related to environmental exposures. It is important to know whether there are any other modifiable environmental risk factors for children’s respiratory health. Two nationwide surveys in 2005 and 2011 were conducted to evaluate prenatal and postnatal risk factors for children's respiratory health problems, including pneumonia, asthma and lung function reduction. Method: The Taiwan Birth Cohort Study (TBCS) was started in 2005. This study analyzed the data collected from the survey at 6-month-old of TBCS. Information on demographics, maternal conditions, postnatal environmental conditions, and hospitalization for pneumonia were inquired by questionnaire. Backward stepwise logistic regression was used to identify potential risk factors. Population attributable risk was calculated for each modifiable risk factor. Between April and May 2011, a nationwide cross-sectional study in Taiwan using a modified Chinese version of the International Study of Asthma and Allergies in Childhood (ISSAC-C) questionnaire was conducted in schoolchildren aged 6~15. There are 264 classrooms randomly sampled from 22 elementary and 22 middle schools. All children in selected classrooms were asked for questionnaire survey. Six of participated non-asthmatic children in each classroom were randomly sampled and asked for further lung function test and collection of oral mucosa and urinary samples. Fungal-spore sampling was conducted for 40 minutes continuously during class in the morning of lung function test using the Burkard Personal Air Sampler. Fungal spores was counted by microscopy and presented as spore counts per cubic meter. Complete monitoring data of air pollution were obtained from 24 Taiwan EPA monitoring stations within 1-km catchment area of selected schools. Hierarchical logistic and linear regression models were applied for statistical analysis on multi-level data. Result: Among the 24200 randomly sampled main caretakers invited, 21248 (87.8%) participated in the 6-month-old TBCS survey. The prevalence of pneumonia was 0.62% in 6-month-old infants. Multivariate logistic regression analysis showed that preterm birth, congenital cardiopulmonary disease, antibiotics use during pregnancy, maternal overweight, daily prenatal exposure to environmental tobacco-smoke, maternal smoking during pregnancy, and visible mold on walls at home are risk factors associated with infantile pneumonia. Our 2011 schoolchildren survey was completed by 6346 out of 7154 parents (88.7%). The prevalences of physician-diagnosed asthma, current asthma, and asthma with symptoms reduced on holidays or weekend (ASROH) were 11.7%, 7.5%, and 3.1%, respectively. The geometric mean spore concentrations of total fungi, Aspergillus/Penicillium, and basidiospores in the 264 classrooms were 2181, 49, and 318 spores/m3. Aspergillus/Penicillium and basidiospores were significantly correlated with current asthma and ASROH after adjusting for personal and school factors. Of those with current asthma, 41% reported relief of symptoms during weekends. In addition, adequate spirograms were obtained from 1494 non-asthmatic children. Lung function changes per inter-quartile increase (16.9 μg/m3, 32-48.9) of the average levels of the past three months of particulate matter <2.5 μm (PM2.5) were -118 ml on FVC, -100 ml on FEV1, and -127 ml/s on MMEF. Lag-1-day ozone exposure was associated with decreased MMEF. In children aged 6-10, PM2.5 was additionally associated with decreased FEV1/FVC and MMEF/FVC ratios. Conclusion: Infantile pneumonia is associated with several modifiable risk factors, including maternal overweight, maternal use of antibiotics, maternal tobacco-smoke exposure, and postnatal exposure to home molds. Current asthma in school children was associated with spore concentrations of Aspergillus/Penicillium and basidiospores in classrooms. In children aged 6-15 years, sub-chronic exposure to ambient PM2.5 leads to reduced lung capacity, whereas acute exposure to ozone decreases mid-expiratory flow. In children aged 6-10 years, additional airway obstructive patterns in lung function are associated with PM2.5 exposure. Our results emphasize the continued need to control environmental risk factors for children’s respiratory health.