Childhood is an important period that affects the body size and eating habits. However, the recent studies have found that birth weight contributes to the development of growth and chronic diseases. Therefore, nutrition status is the key to growth development of children with different birth weights. This study would explore whether dietary nutrition intakes were different in children with different birth weights and how nutrition status benefits the growth development of these children. The study was a cohort study. The subjects were recruited in 2002 and 2004 from two cohorts. The subjects were divided into three groups according to the 25th and 75th percentile cut points: relative low birth weight (rLBW), relative adequate birth weight (rABW) and relative high birth weight (rHBW). Interviewers gathered the 24-hour dietary recalls, anthropometric measures, and other information of children every year by telephone interviews until children was ten. The software packages of SPSS 22.0 and STATA 8.0 were employed for statistical analysis. From birth to 10 years old, the results of anthropometric measurements of different birth groups showed that children of different birth weight groups were significantly different in weight, height and BMI (p<0.05). The rHBW group was always with highest and the rLBW group with the lowest mean among the three groups. We analyzed the various indicators of different growth rates. The prevalence of rLBW in the catch-up group (0~2 year, z >0.67) was significantly higher than rHBW and children of catch-up group was significantly heavier and taller (p<0.05). Energy, protein, fat and carbohydrate intakes of children increased annually but calcium intake was with a mean of 357 mg which was much lower than the recommended value. Although energy per kilogram of body weight and energy nutrients per kilogram of body weight intake decreased year by year, protein per kilogram of body weight intake was higher than the recommended dietary allowance (1.8g/kg at 10). In addition, the energy and nutrient intakes were not significantly different among the three birth weight groups (p>0.05). The results from the correlation analyses showed the energy per kilogram of body weight and energy nutrients per kilogram of body weight intake were negative correlated with the weight, height and BMI at the age of 10 years. By the multiple regression analysis, when the variable of energy per kilogram of body weight and energy nutrients per kilogram of body weight intake singly enter the models, we could find the energy and energy nutrients were negatively associated with the weight, height and BMI at 10. Entering the energy nutrients into the energy model, you found the results that the energy and fat were still negatively correlated with growth indicators at 10 but the protein and carbohydrate were positively with growth indicators. The mean age at adiposity rebound of children in earlier and later rebound groups was five and six years old, respectively. After adiposity rebound of earlier rebound group appeared, the later BMI values of earlier rebound group were higher than later rebound group. Moreover, the protein per kilogram of body weight intake early in life was negatively associated with the age at adiposity rebound. Therefore our data suggested that the children with higher protein intake early in life might have the earlier the adiposity rebound, and consequently, had the higher subsequent BMI. In conclusion, our results showed that birth weight, catch-up growth and adiposity rebound had influence on body size at 10. This study found that the energy per kilogram of body weight and energy nutrients per kilogram of body weight intakes were indicators of children growth status at the same time. Therefore, we should pay attention to provide adequate diet early in life for children to support good growth and health status.