• Made available online as an Accepted Preprint 8 October 2009
  • Accepted Preprint first posted online on 8 October 2009

Catch-up growth after dexamethasone withdrawal occurs in cultured postnatal rat metatarsal bones

  1. Lars Sävendahl
  1. Pediatric Endocrinology Laboratory, Department of Women's and Children's Health, Karolinska Institutet, Stockholm SE-17176, Sweden
  1. (Correspondence should be addressed to A S Chagin who is now at Endocrine Unit, Thier 1101, Massachusetts General Hospital, 50 Blossom Street, Boston, Massachusetts 02114, USA; Email: achagin{at}partners.org)

Abstract

Children exposed to systemic glucocorticoids often exhibit growth retardation and after the cessation of therapy catch-up growth occurs in many, but not all patients. The developmental regulation and underlying cellular mechanisms of catch-up growth are not fully understood. To clarify this issue, we established an in vitro model of catch-up growth. Here we present a protocol for the long-term culture (up to 160 days) of fetal (E20) as well as postnatal (P8) rat metatarsal bones which allowed us to characterize ex vivo the phenomenon of catch-up growth without any influence by systemic factors. The relevance of the model was confirmed by the demonstration that the growth of fetal and postnatal bones were stimulated by IGF1 (100 ng/ml) and inhibited by dexamethasone (Dexa; 1 μM). We found that the capacity to undergo catch-up growth was restricted to postnatal bones. Catch-up growth occurred after postnatal bones had been exposed to Dexa for 7 or 12 days but not after a more prolonged exposure (19 days). Incomplete catch-up growth resulted in compromised bone length when assessed at the end of the 4-month period of culture. While exposure to Dexa was associated with decreased chondrocyte proliferation and differentiation, catch-up growth was only associated with increased cell proliferation. We conclude that the phenomenon of catch-up growth after Dexa treatment is intrinsic to the growth plate and primarily mediated by an upregulation of chondrocyte proliferation.

  • Received in final form 6 October 2009
  • Accepted 8 October 2009
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