Multiple Breath Washout Testing to Identify Pulmonary Chronic Graft Versus Host Disease in Children After Hematopoietic Stem Cell Transplantation.

Pulmonary chronic graft versus host disease (p-cGvHD) is a highly morbid, late complication of hematopoietic stem cell transplantation (HSCT). The 2014 National Institutes of Health cGvHD consensus criteria require a tissue biopsy or a drop in spirometry (with other features) to establish the diagnosis of p-cGvHD. Unfortunately, children are often incapable of performing spirometry, which can delay the diagnosis of this condition. Multiple breath washout testing (MBW) can detect abnormal pulmonary physiology in older children and adults after HSCT, but its feasibility and utility have not been assessed in younger children and in those who cannot perform spirometry. In this study, we assess the feasibility and sensitivity of MBW to detect p-cGvHD in children as young as 3 years of age after HSCT. We performed a cross-sectional analysis of children age 3 to 18 years, between 100 days and 5 years after allogenic HSCT. Participants were recruited from the HSCT population at BC Children's Hospital (Vancouver, Canada). All participants attempted nitrogen MBW, and children age 6 years and over attempted spirometry. Nonparametric statistical techniques were used; descriptive statistics used median (interquartile range [IQR]) and group medians were compared using Wilcoxon rank-sum test. Twenty-six children, median age 11.0 (range 3.6-18.5) years, were recruited a median of 26.4 (IQR 15.7, 51.8) months after HSCT. Six of the 26 children (23%) had a clinical diagnosis of p-cGvHD. MBW was successful in all (26/26, 100%) participants. The lung clearance index (LCI; the primary outcome of MBW) was higher in those with a history of p-cGvHD (median 11.8 [IQR 9.6, 18.7]) than in those with no history of cGvHD (median 7.7 [IQR 7.1, 8.0]; P = .001) or a history of extrapulmonary cGvHD (median 7.5 [IQR 6.9, 7.6], P = .007). A threshold LCI = 9 resulted in a sensitivity of 100% and specificity of 90% for the correct identification of clinically diagnosed p-cGvHD using MBW (area under the receiver operator characteristic curve is 0.97 [95% confidence interval 0.80, 0.99]). Spirometry was successful in most (17/26, 65%) participants. Similar to LCI, forced expiratory volume in 1 second (FEV1)/ forced vital capacity could distinguish between p-cGvHD and no cGvHD (P = .02) and extrapulmonary cGvHD (P = .01). FEV1 alone could not distinguish between either of these groups (P = .87, P = .24 respectively). MBW is feasible in young children after HSCT and in those who cannot perform spirometry. LCI has high discriminative power for correctly identifying p-cGvHD, but these preliminary results require confirmation in a larger validation cohort.

Mitigation of Ventilator-induced Diaphragm Atrophy by Transvenous Phrenic Nerve Stimulation.

RATIONALE: Ventilator-induced diaphragm dysfunction is a significant contributor to weaning difficulty in ventilated critically ill patients. It has been hypothesized that electrically pacing the diaphragm during mechanical ventilation could reduce diaphragm dysfunction. OBJECTIVES: We tested a novel, central line catheter-based, transvenous phrenic nerve pacing therapy for protecting the diaphragm in sedated and ventilated pigs. METHODS: Eighteen Yorkshire pigs were studied. Six pigs were sedated and mechanically ventilated for 2.5 days with pacing on alternate breaths at intensities that reduced the ventilator pressure-time product by 20-30%. Six matched subjects were similarly sedated and ventilated but were not paced. Six pigs served as never-ventilated, never-paced control animals. MEASUREMENTS AND MAIN RESULTS: Cumulative duration of pacing therapy ranged from 19.7 to 35.7 hours. Diaphragm thickness assessed by ultrasound and normalized to initial value showed a significant decline in ventilated-not paced but not in ventilated-paced subjects (0.84 [interquartile range (IQR), 0.78-0.89] vs. 1.10 [IQR, 1.02-1.24]; P = 0.001). Compared with control animals (24.6 µm2/kg; IQR, 21.6-26.0), median myofiber cross-sectional areas normalized to weight and sarcomere length were significantly smaller in the ventilated-not paced (17.9 µm2/kg; IQR, 15.3-23.7; P = 0.005) but not in the ventilated-paced group (24.9 µm2/kg; IQR, 16.6-27.3; P = 0.351). After 60 hours of mechanical ventilation all six ventilated-paced subjects tolerated 8 minutes of intense phrenic stimulation, whereas three of six ventilated-not paced subjects did not (P = 0.055). There was a nonsignificant decrease in diaphragm tetanic force production over the experiment in the ventilated-paced and ventilated-not paced groups. CONCLUSIONS: These results suggest that early transvenous phrenic nerve pacing may mitigate ventilator-induced diaphragm dysfunction.

Impaired learning resulting from respiratory syncytial virus infection.

Respiratory syncytial virus (RSV) is the major cause of respiratory illness in infants worldwide. Neurologic alterations, such as seizures and ataxia, have been associated with RSV infection. We demonstrate the presence of RSV proteins and RNA in zones of the brain--such as the hippocampus, ventromedial hypothalamic nucleus, and brainstem--of infected mice. One month after disease resolution, rodents showed behavioral and cognitive impairment in marble burying (MB) and Morris water maze (MWM) tests. Our data indicate that the learning impairment caused by RSV is a result of a deficient induction of long-term potentiation in the hippocampus of infected animals. In addition, immunization with recombinant bacillus Calmette-Guérin (BCG) expressing RSV nucleoprotein prevented behavioral disorders, corroborating the specific effect of RSV infection over the central nervous system. Our findings provide evidence that RSV can spread from the airways to the central nervous system and cause functional alterations to the brain, both of which can be prevented by proper immunization against RSV.