Disturbances in central respiratory rhythm generation may contribute to breathing disturbances in prematurely born mice

Nearly one million premature infants die annually, due to respiratory distress. While immaturity of the lungs is a major contributor to morbidity and mortality, much less is known about the potential contribution of disturbances in central neuronal networks. Here we tested the hypothesis that central neuronal mechanisms contribute to neonatal apneas and breathing disturbances occurring within the first few hours of life. We used an animal model of prematurity, in which we administered lipopolysaccharide (LPS) into pregnant dams eliciting a maternal inflammatory response that resulted in mouse pups being born prematurely. This experimental model parallels the human condition because a large fraction of human premature births are associated with Chorioamnionitis and other forms of maternal infections. Administration of 5 micrograms of LPS to C57BL/6 mice at G17.5 resulted in delivery of pups at G18.5, about half of which were viable for at least 2 h post delivery. In a flow, whole‐body plethysmograph, premature mice from LPS‐treated dams showed abnormally large breathing patterns occurring at low frequency, which in some pups transitioned to more mature eupneic respiratory activity. Transverse, rhythmically active slices containing the pre‐Bötzinger complex, the putative respiratory rhythm generator, obtained within 30 minutes after birth from LPS pups, showed large amplitude bursts occurring at a slow and irregular frequency. Conversely term and C‐sectioned pups exhibited respiratory rhythmic activity with a smaller and more regular frequency and amplitude. Bath applied caffeine effectively stimulated and regularized burst activity. The in vitro preparations will enable us to compare the cellular mechanisms that underlie the abnormally large breathing patterns seen primarily in premature mouse pups, with the respiratory patterns generated in term and c‐sectioned pups. Understanding the central mechanisms that underlie disordered breathing in prematurity may lead to novel treatment strategies for neonatal apneas and breathing failures in human infants. Support or Funding Information Investigators Inter‐center seed funds