Department of Neonatology, Emma Children's Hospital, Academic Medical Center, Amsterdam, The Netherlands.
J Pediatr. 2013 Apr;162(4):691-7. doi: 10.1016/j.jpeds.2012.09.027. Epub 2012 Oct 25.
To monitor regional changes in end-expiratory lung volume (EELV), tidal volumes, and their ventilation distribution during different levels of nasal continuous positive airway pressure (nCPAP) and nasal biphasic positive airway pressure (BiPAP) in stable preterm infants.
By using electrical impedance tomography and respiratory inductive plethysmography, we measured changes in EELV and tidal volumes in 22 preterm infants (gestational age 29.7 ± 1.5 weeks) during 3 nCPAP levels (2, 4, and 6 cmH2O) and unsynchronized BiPAP (nCPAP = 6 cmH2O; pressure amplitude = 3 cmH2O; frequency = 50/min; inspiration time = 0.5 seconds) at 10-minute intervals. We assessed the distribution of these volumes in ventral and dorsal chest regions by using electrical impedance tomography.
EELV increased with increasing nCPAP with no difference between the ventral and dorsal lung regions. Tidal volume also increased, and a decrease in phase angle and respiratory rate was noted by respiratory induction plethysmography. At the regional level, electrical impedance tomography data showed a more dorsally oriented ventilation distribution. BiPAP resulted in a small increase in EELV but without changes in tidal volume or its regional distribution.
Increasing nCPAP in the range of 2 to 6 cmH2O results in a homogeneous increase in EELV and an increase in tidal volume in preterm infants with a more physiologic ventilation distribution. Unsynchronized BiPAP does not improve tidal volume compared with nCPAP.
监测稳定早产儿在不同水平经鼻持续气道正压通气(nCPAP)和经鼻双相气道正压通气(BiPAP)时呼气末肺容积(EELV)、潮气量及其通气分布的区域变化。
通过使用电阻抗断层成像和呼吸感应容积描记法,我们在 22 名早产儿(胎龄 29.7±1.5 周)中测量了 3 种 nCPAP 水平(2、4 和 6 cmH2O)和非同步 BiPAP(nCPAP=6 cmH2O;压力幅度=3 cmH2O;频率=50/min;吸气时间=0.5 秒)时,EELV 和潮气量在 10 分钟间隔内的变化。我们通过电阻抗断层成像评估这些容积在胸腹部的分布。
EELV 随 nCPAP 的增加而增加,且在背侧和腹侧肺区之间无差异。潮气量也增加,呼吸感应容积描记法显示相角和呼吸频率降低。在区域水平,电阻抗断层成像数据显示通气分布更偏向于背部。BiPAP 导致 EELV 略有增加,但潮气量及其区域分布无变化。
在 2 至 6 cmH2O 范围内增加 nCPAP 可使 EELV 均匀增加,并使早产儿潮气量增加,通气分布更符合生理。与 nCPAP 相比,非同步 BiPAP 并不能增加潮气量。
