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01.12.2015 | Research article | Ausgabe 1/2015 Open Access

BMC Physiology 1/2015

Effects of postnatal growth restriction and subsequent catch-up growth on neurodevelopment and glucose homeostasis in rats

BMC Physiology > Ausgabe 1/2015
Erica E. Alexeev, Bo Lönnerdal, Ian J. Griffin
Wichtige Hinweise

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

EEA carried out the animal experiments and assays, interpreted data, and drafted the manuscript. BL participated in the study design, data interpretation, and revised the manuscript. IJG conceived the study and performed the statistical analysis, participated in data interpretation, and also revised the manuscript. All authors read and approved the final manuscript.



There is increasing evidence that poor growth of preterm infants is a risk factor for poor long-term development, while the effects of early postnatal growth restriction are not well known. We utilized a rat model to examine the consequences of different patterns of postnatal growth and hypothesized that early growth failure leads to impaired development and insulin resistance. Rat pups were separated at birth into normal (N, n = 10) or restricted intake (R, n = 16) litters. At d11, R pups were re-randomized into litters of 6 (R-6), 10 (R-10) or 16 (R-16) pups/dam. N pups remained in litters of 10 pups/dam (N-10). Memory and learning were examined through T-maze test. Insulin sensitivity was measured by i.p. insulin tolerance test and glucose tolerance test.


By d10, N pups weighed 20 % more than R pups (p < 0.001). By d15, the R-6 group caught up to the N-10 group in weight, the R-10 group showed partial catch-up growth and the R-16 group showed no catch-up growth. All R groups showed poorer scores in developmental testing when compared with the N-10 group during T-Maze test (p < 0.05). Although R-16 were more insulin sensitive than R-6 and R-10, all R groups were more glucose tolerant than N-10.


In rats, differences in postnatal growth restriction leads to changes in development and in insulin sensitivity. These results may contribute to better elucidating the causes of poor developmental outcomes in human preterm infants.
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