Short apneas and periodic breathing in preterm infants in the neonatal intensive care unit-Effects of sleep position, sleep state, and age.

This observational study investigated the effects of sleep position and sleep state on short apneas and periodic breathing in hospitalized preterm infants longitudinally, in relation to postmenstrual age. Preterm infants (25-31 weeks gestation, n = 29) were studied fortnightly after birth until discharge, in prone and supine positions, and in quiet sleep and active sleep. The percentage of time spent in each sleep state (percentage of time in quiet sleep and percentage of time in active sleep), percentage of total sleep time spent in short apneas and periodic breathing, respectively, the percentage of falls from baseline in heart rate, arterial oxygen saturation and cerebral tissue oxygenation index during short apneas and periodic breathing, and the associated percentage of total sleep time with systemic (arterial oxygen saturation < 90%) and cerebral hypoxia (cerebral tissue oxygenation index < 55%) were analysed using a linear mixed model. Results showed that the prone position decreased (improved) the percentage of falls from baseline in arterial oxygen saturation during both short apneas and periodic breathing, decreased the proportion of infants with periodic breathing and the periodic breathing-associated percentage of total sleep time with cerebral hypoxia. The percentage of time in quiet sleep was higher in the prone position. Quiet sleep decreased the percentage of total sleep time spent in short apneas, the short apneas-associated percentage of falls from baseline in heart rate, arterial oxygen saturation, and proportion of infants with systemic hypoxia. Quiet sleep also decreased the proportion of infants with periodic breathing and percentage of total sleep time with cerebral hypoxia. The effects of sleep position and sleep state were not related to postmenstrual age. In summary, when sleep state is controlled for, the prone sleeping position has some benefits during both short apneas and periodic breathing. Quiet sleep improves cardiorespiratory stability and is increased in the prone position at the expense of active sleep, which is critical for brain maturation. This evidence should be considered in positioning preterm infants.

Prone sleeping affects cardiovascular control in preterm infants in NICU.

BACKGROUND: Prone sleeping is used in preterm infants undergoing intensive care to improve respiratory function, but evidence suggests that this position may compromise autonomic cardiovascular control. To test this hypothesis, this study assessed the effects of the prone sleeping position on cardiovascular control in preterm infants undergoing intensive care treatment during early postnatal life. METHODS: Fifty-six preterm infants, divided into extremely preterm (gestational age (GA) 24-28 weeks, n = 23) and very preterm (GA 29-34 weeks, n = 33) groups, were studied weekly for 3 weeks in prone and supine positions, during quiet and active sleep. Heart rate (HR) and non-invasive blood pressure (BP) were recorded and autonomic measures of HR variability (HRV), BP variability (BPV), and baroreflex sensitivity (BRS) using frequency analysis in low (LF) and high (HF) bands were assessed. RESULTS: During the first 3 weeks, prone sleeping increased HR, reduced BRS, and increased HF BPV compared to supine. LF and HF HRV were also lower prone compared to supine in very preterm infants. Extremely preterm infants had the lowest HRV and BRS measures, and the highest HF BPV. CONCLUSIONS: Prone sleeping dampens cardiovascular control in early postnatal life in preterm infants, having potential implications for BP regulation in infants undergoing intensive care.

Effects of Prone Sleeping on Cerebral Oxygenation in Preterm Infants.

OBJECTIVE: To determine the effect of prone sleeping on cerebral oxygenation in preterm infants in the neonatal intensive care unit. STUDY DESIGN: Preterm infants, divided into extremely preterm (gestational age 24-28 weeks; n = 23) and very preterm (gestational age 29-34 weeks; n = 33) groups, were studied weekly until discharge in prone and supine positions during active and quiet sleep. Cerebral tissue oxygenation index (TOI) and arterial oxygen saturation (SaO2) were recorded. Cerebral fractional tissue extraction (CFOE) was calculated as CFOE = (SaO2 - TOI)/SaO2. RESULTS: In extremely preterm infants, CFOE increased modestly in the prone position in both sleep states at age 1 week, in no change in TOI despite higher SaO2. In contrast, the very preterm infants did not have position-related differences in CFOE until the fifth week of life. In the very preterm infants, TOI decreased and CFOE increased with active sleep compared with quiet sleep and with increasing postnatal age. CONCLUSION: At 1 week of age, prone sleeping increased CFOE in extremely preterm infants, suggesting reduced cerebral blood flow. Our findings reveal important physiological insights in clinically stable preterm infants. Further studies are needed to verify our findings in unstable preterm infants regarding the potential risk of cerebral injury in the prone sleeping position in early postnatal life.

Human papillomavirus 16-specific T-cell responses and spontaneous regression of anal high-grade squamous intraepithelial lesions.

BACKGROUND: Most anal cancers are attributable to persistent human papillomavirus type 16 (HPV-16) infection. The anal cancer precursor, high-grade squamous intraepithelial lesion (HSIL), frequently regresses spontaneously. We hypothesized that T-cell responses are associated with HSIL regression. METHODS: In men who have sex with men undergoing anal cytology and high-resolution anoscopy, we measured responses to HPV-16 oncogenic proteins E6 and E7, using the CD25/CD134 assay for CD4(+) antigen-specific T cells and intracellular cytokine staining for CD4(+) and CD8(+) antigen-specific T cells. RESULTS: Of 134 participants (mean [SD] age, 51 [9.3] years; 31 [23.1%] infected with human immunodeficiency virus), 51 (38.1%) had HSIL. E6- and E7-specific CD4(+) T-cell responses were detected in 80 (59.7%) and 40 (29.9%) of the participants, respectively, and E6- and E7-specific CD8(+) T-cell responses were each detected in 25 (18.7%). HSIL was significantly associated with E7-specific CD8(+) T-cell responses (odds ratio, 4.09 [95% confidence interval, 1.55-10.77], P = .004), but not with any CD4(+) T-cell response (P ≥ .09). Twenty-six participants had HSIL a mean of 1 year before measurement of T-cell responses, and 6 (23%) of them were regressors. Five regressors (83%) had E6-specific CD4(+) T-cell responses vs 7 of 20 (35%) nonregressors (Pexact = .065). CONCLUSIONS: Systemic HPV-16 E6- and E7-specific T-cell responses were common in men who have sex with men. E6-specific CD4(+) T-cell responses may be associated with recent HSIL regression. CLINICAL TRIALS REGISTRATION: NCT02007421.

Insights into the effects of sleep disordered breathing on the brain in infants and children: Imaging and cerebral oxygenation measurements.

Sleep disordered breathing (SDB) is a common condition in infants and children. SDB encompasses a spectrum of respiratory disorders, which are defined as either obstructive or central in nature. Obstructive SDB ranges in severity from primary snoring (PS), to obstructive sleep apnea (OSA). There are a number of conditions characterized by central sleep apnea (CSA), including but not limited to periodic breathing in infants, Arnold Chiari malformations, and idiopathic CSA. SDB is associated with adverse cardiovascular and neurocognitive outcomes believed to be the consequence of the repeated cycles of hypoxia followed by reperfusion, hypercarbia, and sleep fragmentation. The peripheral hypoxia in individuals with SDB may not reflect cerebral oxygenation, and near infrared spectroscopy (NIRS) has been used to determine oxygen delivery and uptake in the brain. Neuroimaging in the form of structural and functional magnetic resonance imaging (MRI, fMRI), diffusion tensor imaging (DTI), and magnetic resonance spectroscopy (MRS) have become widely used to determine the structural, functional and chemical changes in the brain associated with SDB. This review will explore the relationship between central and obstructive SDB and changes in cerebral oxygenation together with changes in brain structure and function, in infants and children. It is important to identify any adverse effects so that they can be mitigated as early as possible to minimize any detrimental effects on the developing brain.

The Cerebral Hemodynamic Response to Pain in Preterm Infants With Fetal Growth Restriction.

Background: Preterm infants undergoing intensive care often experience painful procedures such as heel lance for blood sampling. Knowledge of the cerebral hemodynamic response to painful stimuli contributes to understanding of cortical pain processing and the neurovascular network in the preterm brain. Previous research has demonstrated cerebral hemodynamic responses using near-infrared spectroscopy (NIRS) after noxious stimuli in infants appropriately grown for age (AGA). But this has not been studied in infants born small for gestational age after fetal growth restriction (FGR). FGR infants differ in brain development due to utero-placental insufficiency leading to the intrauterine growth restriction, and cerebral response to pain may be altered. Objectives: We aimed to compare the cerebral hemodynamic response to painful stimuli (heel lance) in FGR and AGA infants. Methods: Preterm FGR infants (n = 20) and AGA infants (n = 15) born at 28-32 weeks' gestation were studied at mean ± SD postnatal age of 11.5 ± 2.4 and 10.5 ± 2.4 days, respectively. Infants had baseline echocardiographic assessment of ductus arteriosus and stroke volume. They were monitored with NIRS for changes in tissue oxygenation index (TOI, %), and oxygenated, deoxygenated, and total hemoglobin (ΔO2Hb, ΔHHb, and ΔTHb) in contralateral and ipsilateral cerebral hemispheres, during a heel lance. Results: At baseline, FGR infants had significantly lower TOI, higher heart rate, and lower stroke volume compared to AGA infants. Most infants in both groups showed increase in each of the NIRS parameters in the contralateral hemisphere following heel lance. However, more AGA infants (6/15) showed decreased ΔTHb compared to FGR infants (1/20) (p = 0.016). The magnitude of cerebral hemodynamic response and time to response did not differ between FGR and AGA infants. FGR infants showed larger ΔO2Hb in the contralateral compared to ipsilateral cortex (p = 0.05). Conclusion: Preterm FGR infants have reduced stroke volume and lower cerebral oxygenation compared to AGA infants in the second to third week of life. FGR infants show similar cerebral hemodynamic responses to noxious stimuli compared to AGA infants. However, FGR infants are less likely to have a cerebral vasoconstrictive response, possibly due to cerebrovascular changes following placental insufficiency and brain sparing in-utero.

When does prone sleeping improve cardiorespiratory status in preterm infants in the NICU?

STUDY OBJECTIVES: Preterm infants undergoing intensive care are often placed prone to improve respiratory function. Current clinical guidelines recommend preterm infants are slept supine from 32 weeks' postmenstrual age, regardless of gestational age at birth. However, respiratory function is also related to gestational and chronological ages and is affected by sleep state. We aimed to identify the optimal timing for adopting the supine sleeping position in preterm infants, using a longitudinal design assessing the effects of sleep position and state on cardiorespiratory stability. METHODS: Twenty-three extremely (24-28 weeks' gestation) and 33 very preterm (29-34 weeks' gestation) infants were studied weekly from birth until discharge, in both prone and supine positions, in quiet and active sleep determined by behavioral scoring. Bradycardia (heart rate ≤100 bpm), desaturation (oxygen saturation ≤80%), and apnea (pause in respiratory rate ≥10 s) episodes were analyzed. RESULTS: Prone positioning in extremely preterm infants reduced the frequency of bradycardias and desaturations and duration of desaturations. In very preterm infants, prone positioning only reduced the frequency of desaturations. The position-related effects were not related to postmenstrual age. Quiet sleep in both preterm groups was associated with fewer bradycardias and desaturations, and also reduced durations of bradycardia and desaturations in the very preterm group. CONCLUSIONS: Cardiorespiratory stability is improved by the prone sleep position, predominantly in extremely preterm infants, and the improvements are not dependent on postmenstrual age. In very preterm infants, quiet sleep has a more marked effect than the prone position. This evidence should be considered in individualizing management of preterm infant positioning.

Prone sleeping position in infancy: Implications for cardiovascular and cerebrovascular function.

Advances in neonatal care have improved the survival rates of preterm infants, however, the likelihood of brain injury and neurodevelopmental disability remains a significant problem. Whilst the etiology of preterm brain injury is complex, impairments in the cardio- and cerebro-vascular function have been implicated. During infancy, sleep is vital for brain development. However, instabilities in cardio- and cerebro-vascular function are most marked during sleep. Sleeping position is an important part of a safe sleeping environment. Prone sleeping increases the risk of sudden infant death syndrome and is associated with reduced blood pressure, cerebral oxygenation and impaired autonomic cardiovascular control in infants born at term. Importantly, these effects are amplified by preterm birth. Hospitalized preterm infants are often slept in the prone position to improve respiratory function. However, there is little consensus regarding the sustained benefits of prone sleeping in this population. In light of the impaired cardio- and cerebro-vascular function during prone sleeping in term and preterm infants after hospital discharge, the likely adverse effects of prone sleeping in hospitalized preterm infants are concerning. This review examines the cardiovascular and cerebrovascular effects of prone sleeping in infants born at term, those born preterm after term equivalent age and whilst hospitalized.