Oxalates in oca (New Zealand yam) (Oxalis tuberosa Mol.).

Oca (Oxalis tuberosa Mol.) or New Zealand yam, in common with other members of this genus, contains oxalate, an antinutritive factor. Twelve South American and two New Zealand cultivars of oca were analyzed for total and soluble oxalate contents of the tubers. The range of total oxalate levels was 92-221 mg/100 g of fresh weight. Levels of soluble and total oxalate extracted from the tubers were not significantly different, suggesting that no calcium oxalate is formed in the tubers. The oxalate concentrations obtained in this study for oca suggest that previously reported values are too low and that oca is a moderately high oxalate-containing food. This is the first report of a tuber crop containing moderate to high levels of soluble oxalates in the tubers and no insoluble oxalates.

Persistence of the biphasic ventilatory response to hypoxia in preterm infants.

OBJECTIVE: To characterize postnatal maturation of the biphasic ventilatory response to hypoxia in order to determine whether it persists beyond the first weeks of life in preterm infants, and the contributions of respiratory frequency and tidal volume to this response. METHODS: Stable preterm infants were studied at two postnatal ages, 2 to 3 weeks (n = 12) and 4 to 8 weeks (n = 12), before hospital discharge at 35 weeks (range, 33 to 38 weeks) of postconceptional age. Infants were exposed to 5 minutes of 15% (or 13%) inspired oxygen; ventilation, oxygen saturation, end-tidal partial pressure of carbon dioxide, and heart rate were simultaneously recorded. RESULTS: Minute ventilation exhibited a characteristic biphasic response to hypoxia at both postnatal ages, regardless of the development of periodic breathing. At both ages there was a transient increase in tidal volume, which peaked at 1 minute, accompanied by a sustained decrease in respiratory frequency as a result of significant prolongation of expiratory time. CONCLUSION: The characteristic biphasic ventilatory response to hypoxia persists into the second month of postnatal life in preterm infants. We speculate that this finding is consistent with the prolonged vulnerability of such infants to neonatal apnea.

Characteristics of hypoxemic episodes in very low birth weight infants on ventilatory support.

OBJECTIVE: To characterize hypoxemic episodes in very low birth weight infants with mechanically ventilated lungs and to describe their natural history and the effect of body position. STUDY DESIGN: Tidal volume, respiratory rate, oxygen saturation, heart rate, and body movement were continuously recorded in 10 very low birth weight infants who exhibited episodes of hypoxemia during mechanical ventilation (birth weight, 810 +/- 133 gm; postconceptional age at study, 30 +/- 1.6 weeks). Frequency of hypoxemic episodes was compared in both prone and supine positions. RESULTS: Seventy-eight percent of hypoxemic episodes began in association with body movement as well as heart rate acceleration. Thereafter the spontaneous and delivered minute ventilation both decreased during the first 15 seconds of hypoxemia. The former decrease was due to a significant decrease in frequency of spontaneous respiration, whereas the latter was associated with a significant decrease in delivered tidal volume. Minute ventilation returned to normal before recovery of oxygenation. A change in body position from supine to prone significantly decreased the frequency of hypoxemic episodes. CONCLUSION: Hypoxemic episodes in infants who are on ventilatory support are characterized by (1) movement and cardioacceleration at initiation; (2) a decrease in both spontaneous and delivered minute ventilation, and (3) a lower incidence in the prone position. We speculate that spontaneous movement during sleep can trigger cardiopulmonary reflex responses that initiate and propagate these episodes.

Vulnerability of respiratory control in healthy preterm infants placed supine.

OBJECTIVE: We tested the hypothesis that healthy preterm infants have attenuated ventilatory responses to hypercapnia, associated with a decreased rib cage contribution to ventilation, in the supine versus prone position. STUDY DESIGN: We elicited hypercapnic ventilatory responses from 19 healthy preterm infants (postconceptional age 35 +/- 1 weeks) who were being prepared for hospital discharge. The O2 saturation was continuously monitored. Before and during CO2 rebreathing, ventilation was measured with a nasal mask pneumotachygraph and was derived from chest wall motion as determined by respiratory inductance plethysmograph. This measuring method allowed us to compare both ventilation and the percentage rib cage contribution to ventilation between supine and prone positions. Statistical analysis employed analysis of variance with repeated measures. RESULTS: The supine position was associated with a higher respiratory rate (p < 0.02) and lower O2 saturation (p < 0.007) than the prone position. The increase in ventilation in response to hypercapnia was lower in the supine than in the prone position. This was statistically significant for the respiratory inductance plethysmograph (p < 0.008) but not the pneumotachygraph (p = 0.077), and was associated with a smaller rib cage contribution to ventilation in the supine than in the prone position (p < 0.0001). CONCLUSION: Respiratory control may be vulnerable when healthy preterm infants are placed supine. Widespread avoidance of the prone position may not be appropriate for such patients.

Increased respiratory drive as an inhibitor of oral feeding of preterm infants.

This study was designed to determine whether increased respiratory drive induced by inhalation of carbon dioxide would alter the reflex and voluntary components of feeding. For 10 preterm infants (mean +/- SD: postconceptional age at study, 34 +/- 2 weeks; weight, 2.1 +/- 0.2 kg), four trials of nutritive feeding were offered: two while the infants were inhaling a gas mixture containing 40% oxygen and two while the infants were breathing 40% oxygen and 7% carbon dioxide. Nasal airflow was monitored with a pneumotachygraph. Pressure-sensitive catheters in the esophagus and in the feeding nipple were used to detect swallowing and sucking. Sucking frequency and pattern, rate of swallowing, end-tidal carbon dioxide, and minute ventilation were recorded for 30-second epochs during feeding. When the inhaled gas mixture was switched from 40% oxygen to 40% oxygen and 7% carbon dioxide, sucking frequency decreased from 53 +/- 10 to 48 +/- 12 and from 54 +/- 12 to 40 +/- 19 sucks/min, respectively (p < 0.005). Frequency of swallowing also fell during the two feeding epochs on 7% carbon dioxide, from 45 +/- 15 to 40 +/- 15 and from 43 +/- 14 to 31 +/- 16 swallows/min (p < 0.003). Thus acute hypercapnea was accompanied by a decrease in rate of both sucking and swallowing during nutritive feeding. Increased ventilatory drive may directly inhibit nutritive feeding behavior in premature infants.

Early randomized intervention with high-frequency jet ventilation in respiratory distress syndrome.

To determine whether early use of high-frequency jet ventilation reduces neonatal mortality or pulmonary morbidity rates, we randomly selected 42 infants with clinical and radiographic evidence of severe respiratory distress syndrome to receive either high-frequency jet ventilation or conventional ventilation. Separate sequential analyses (two-sided, alpha = 0.05, power = 0.95 to detect 85:15 advantage) were performed for mortality rates, air leaks, bronchopulmonary dysplasia, intraventricular hemorrhage, and assignment crossover, and a combined analysis was performed, with death overriding other outcome variables. Enrollment was completed when the combined analysis reached the sequential design boundary indicating no treatment difference. Mortality rates (19% among infants receiving high-frequency jet ventilation vs 24% among infants receiving conventional ventilation), the incidence of air leaks (48% vs 52%), bronchopulmonary dysplasia (39% vs 41%), and intraventricular hemorrhage (33% vs 43%), and assignment crossovers (14% vs 24%) did not differs significantly between the treatment groups. We conclude that early use of high-frequency jet ventilation does not prevent or substantially reduce mortality or morbidity rates associated with assisted ventilation.

Effect of head position on distribution of nasal airflow in preterm infants.

Supine preterm infants characteristically adopt a lateral head position; however, it is not known whether this influences the distribution of nasal airflow. Ventilation was measured in 12 healthy preterm infants (postconceptional age 34 +/- 2 weeks) by employing a nasal mask pneumotachygraph that separated airflow between the left and right nasal passages. In the midline supine position, the percent of total tidal volume (%VT) through the right nasal passage ranged from 31% to 64% and varied by less than 5% between active and quiet sleep in any infant. Lateral positioning of the head caused %VT to increase on the dependent side and decrease through the upper nasal passage. When the right side was dependent, mean %VT on that side increased from 52 +/- 9% to 67 +/- 14% (P less than 0.01) and decreased to 43 +/- 10% (P less than 0.05) when the right side was up. In the midline position, the presence of a nasogastric tube caused %VT through the nasal passage with the tube to fall from 54 +/- 8% to 39 +/- 8% (P less than 0.01). The %VT fell farther, to 25 +/- 10% (P less than 0.01), when the nasal passage with the nasogastric tube was up. Despite these changes in VT distribution, total VT remained constant during these maneuvers. We speculate that when supine preterm infants adopt a lateral head position, the decrease in airflow through the upper nasal passage results from partial obstruction of the oropharyngeal or nasopharyngeal airway on that side.

Randomized trial of high-frequency jet ventilation versus conventional ventilation in respiratory distress syndrome.

To compare high-frequency jet ventilation (HFJV) with pressure-limited time-cycled conventional ventilation (CV), we randomized 41 infants with clinical and radiographic evidence of respiratory distress syndrome during the first day of life to receive either HFJV or CV. Standardized ventilatory protocols were used for 48 hours, after which CV was administered to both groups. Despite comparable oxygenation (arterial/alveolar oxygen tension ratio), mean airway pressure was lower in the HFJV group (9 +/- 2 vs 13 +/- 2 cm H2O, P less than 0.001), and thus the arterial/alveolar oxygen tension ratio corrected for mean airway pressure was improved in the HFJV group (P less than 0.05). PaCO2 was lower during HFJV (37 +/- 3 vs 42 +/- 3 mm Hg, P less than 0.05) despite a comparable peak inspiratory pressure. The incidence of air leaks, progression of intraventricular hemorrhage, and mortality during the 48-hour period did not differ between the two groups. Bronchoscopies in eight infants given HFJV and five given CV revealed no microscopic evidence of necrotizing tracheobronchitis, but one infant given HFJV had evidence of necrotizing tracheitis at autopsy. We conclude that for 48 hours during the acute stage of respiratory distress syndrome, HFJV can maintain adequate gas exchange at lower mean airway pressure than during CV, without an increase in the incidence of side effects.

Effect of maturation on oral breathing in sleeping premature infants.

To evaluate the influence of postnatal maturation on oral breathing, we measured nasal and oral ventilation during sleep and the ventilatory response to nasal occlusion in 11 preterm infants. Studies were repeated at 31-32, 33-34, and 35-36 weeks postconceptional age. Premature infants had rare episodes of spontaneous oronasal breathing during sleep. The frequency of oral breathing in response to nasal occlusion increased with advancing postconceptional age, from 8% +/- 8% at 31-32 weeks to 26% +/- 18% at 33-34 weeks and 28% +/- 33% at 35-36 weeks. Oral breathing in preterm infants, unlike that in term infants, was characterized by intermittent airway obstruction leading to a significant decrease in respiratory rate, tidal volume, minute ventilation, and tcpo2 (P less than 0.005). When inspiratory (Rl) and expiratory (RE) resistances during nasal and oral breathing were compared, Rl increased from 41 +/- 30 to 234 +/- 228 (P less than 0.004) and RE from 62 +/- 16 to 145 +/- 43 cm H2O X L-1 X sec (P less than 0.004). The ability of preterm infants to use the oral route of breathing thus increases with advancing postnatal maturation, but its effectiveness may remain limited by high oral airway resistance.

Effect of varying inspiratory and expiratory times during high-frequency jet ventilation.

Although high-frequency jet ventilation may reduce barotrauma, the optimal ventilator settings at which complications are minimized have not been determined. To develop ventilator strategies applicable to the human infant, we studied six New Zealand rabbits before and after saline lung lavage. Changes in functional residual capacity (delta FRC) and airway pressure gradient (peak inspiratory pressure minus positive end-expiratory pressure) were measured while inspiratory time (TI) and expiratory time (TE) were varied. Frequencies of 120, 240, and 480 cycles per minute and inspiratory to expiratory ratios of 1:1, 1:3, 1:5, and 1:9 resulted in TI that varied from 12 to 250 msec, and TE from 62 to 450 msec. Analysis of variance demonstrated that as TI was shortened, a significantly higher airway pressure gradient was necessary to maintain a constant tidal volume. As TE was shortened, air trapping, as determined from both inadvertent positive end-expiratory pressure and delta FRC, significantly increased. Lung lavage increased the airway pressure gradient at each TI, but decreased air trapping at each TE. At no time did entrainment contribute to the delivered tidal volume. We conclude that a relatively narrow range of TI and TE may be necessary for optimal use of high-frequency jet ventilation to reduce airway pressures and minimize the risk of air trapping.

Oral breathing in newborn infants.

Newborn infants are considered obligate nasal breathers, hence dependent on a patent nasal airway for ventilation. The conditions under which oral breathing could occur and the contribution of oral ventilation to total ventilation were studied in 30 healthy term infants (aged 1 to 3 days). Nasal and oral airflow were measured using two resistance-matched pneumotachometers, and heart rate, tcPO2, etCO2, and sleep state were continuously recorded. In three of 10 infants studied in undisturbed sleep, spontaneous oronasal breathing was noted during both active and quiet sleep (mean duration 19 +/- 25 minutes), the distribution of tidal volume being 70% +/- 12% nasal and 30% +/- 12% oral. Episodes of oronasal breathing were also observed after crying in six infants (mean duration 21 +/- 19 seconds). In an additional 20 infants, multiple 15-second end-expiratory nasal occlusions were performed; eight (40%) of these infants initiated and sustained oral breathing in response to nasal occlusion. Respiratory rate, tidal volume, heart rate, and tcPO2 did not change when oral breathing occurred in response to nasal occlusion, although minute ventilation decreased from 265 to 199 ml/min/kg (P less than 0.05). These results demonstrate that newborn infants may use the oral airway for ventilation, both spontaneously and in response to complete nasal occlusion.

Continuous positive airway pressure selectively reduces obstructive apnea in preterm infants.

Apnea in preterm infants has been classified as obstructive, central (nonobstructive), and mixed, based on the presence or absence of upper airway obstruction. Continuous positive airway pressure (CPAP) is widely used in apneic infants, although its mechanism of action is still unclear. To determine whether CPAP is equally effective in obstructive and nonobstructive apnea, we compared the types of apnea observed in 14 preterm infants during sequential 45-minute periods with and without CPAP. CPAP markedly decreased the incidence of both mixed and obstructive apnea episodes of greater than or equal to 5 seconds (P less than 0.01 and less than 0.03, respectively). In contrast, central apnea episodes of greater than or equal to 5 seconds were entirely unaffected by CPAP. Although minute ventilation was unchanged, transcutaneous PO2 increased by 11 +/- 11 mm Hg during CPAP whether or not apnea was present. We postulate that CPAP reduces apnea in preterm infants by relief of upper airway obstruction, possibly via splinting of the pharyngeal airway.

Decrease in airway pressure during high-frequency jet ventilation in infants with respiratory distress syndrome.

Using a crossover study design, we compared a system of high-frequency jet ventilation with appropriate humidification to pressure-limited conventional ventilation in 12 preterm infants with a birth weight of 1.9 +/- 0.6 kg and gestational age of 32 +/- 2 weeks who had severe respiratory distress syndrome. After a control period of conventional ventilation, high-frequency jet ventilation was administered for 1 to 3 hours at a constant rate (250/min) and inspiratory to expiratory time (1:3 or 1:4) in the same fraction of inspired oxygen as during conventional ventilation. Average peak inspiratory pressure decreased from 29 +/- 3 cm H2O during conventional ventilation to 20 +/- 4 cm H2O during high-frequency jet ventilation (P less than 0.001), whereas positive end expiratory pressure was unchanged, resulting in a reduction in mean airway pressure from 14 +/- 3 to 10 +/- 2 cm H2O (P less than 0.001). There was a simultaneous decrease in PaCO2 (39 +/- 4 to 34 +/- 4 mm Hg, P less than 0.01), but PaO2 did not change. These data indicate that short-term high-frequency jet ventilation maintains gas exchange in infants with respiratory distress syndrome despite a lower PIP and Paw, and results in smaller airway pressure swings than during conventional ventilation. Thus, high-frequency jet ventilation may offer hope for reducing barotrauma in this population.

Decreased ventilation in preterm infants during oral feeding.

As respiratory difficulty may accompany nipple feeding in preterm neonates, we studied the effect of oral feeding on ventilation in 23 preterm infants. The infants composed two groups based on their postconceptional age at the time of study: Group A comprised 12 infants 34 to 35.9 weeks of age, and group B, 11 infants 36 to 38 weeks. Ventilation was measured via a nasal mask pneumotachometer, and sucking pressure via a nipple that also permitted milk delivery; transcutaneous PO2 and PCO2 were continuously monitored. The feeding pattern comprised an initial period of continuous sucking of at least 30 seconds, followed by intermittent sucking bursts for the remainder of the feed. When compared with an initial semi-upright control period, minute ventilation (V1) during continuous sucking fell by 52 +/- 6% (P less than 0.001) and 40 +/- 2% (P less than 0.001) in groups A and B, respectively. This was the result of a decrease in respiratory frequency and tidal volume and was associated with a fall in TcPO2 of 13 +/- 4 mm Hg (P less than 0.01) in group A and 10 +/- 2 mm Hg (P less than 0.01) in group B. During intermittent sucking, V1 and TcPO2 recovered partially only in the more mature infants (group B). At the end of the feed, TcPCO2 have risen by 3 +/- 1 mm Hg (P less than 0.001) in group A and by 2 +/- 2 mm Hg (P less than 0.05) in group B. Thus oral feeding results in an impairment of ventilation during continuous sucking and the subsequent recovery during intermittent sucking is dependent on postconceptional age.