Respiratory Support of Infants With Congenital Diaphragmatic Hernia

Optimisation of respiratory support of infants with congenital diaphragmatic hernia (CDH) is critical. Infants with CDH often have severe lung hypoplasia and abnormal development of their pulmonary vasculature, leading to ventilation perfusion mismatch. It is vital that lung protective ventilation strategies are employed during both initial stabilisation and post-surgical repair to avoid ventilator induced lung damage and oxygen toxicity to prevent further impairment to an already diminished gas-exchanging environment. There is a lack of robust evidence for the routine use of surfactant therapy during initial resuscitation of infants with CDH and thus administration cannot be recommended outside clinical trials. Additionally, inhaled nitric oxide has been shown to have no benefit in reducing the mortality rates of infants with CDH. Other therapeutic agents which beneficially act on pulmonary hypertension are currently being assessed in infants with CDH in randomised multicentre trials. The role of novel ventilatory modalities such as closed loop automated oxygen control, liquid ventilation and heliox therapy may offer promise for infants with CDH, but the benefits need to be determined in appropriately designed clinical trials.

Knowledge Gaps in the Fetal to Neonatal Transition of Infants With a Congenital Diaphragmatic Hernia

Clinical research for infants born with a congenital diaphragmatic hernia (CDH) has until recently mainly focused on advances in prenatal and postnatal treatment. However, during the early perinatal transition period there are major physiological adaptations. For most infants these changes will happen uneventfully, but for CDH infants this marks the beginning of serious respiratory complications. In recent years, there is emerging evidence that the clinical management during the perinatal stabilization period in the delivery room may influence postnatal outcomes. Herein, we discuss major knowledge gaps and novel concepts that aim to optimize fetal to neonatal transition for infants with CDH. One such novel and interesting approach is performing resuscitation with an intact umbilical cord, the efficacy of this procedure is currently being investigated in several clinical trials. Furthermore, close evaluation of neonatal physiological parameters in the first 24 h of life might provide early clues concerning the severity of lung hypoplasia and the risk of adverse outcomes. We will provide an overview of trending concepts and discuss potential areas for future research.

Cellular Origin(s) of Congenital Diaphragmatic Hernia

Congenital diaphragmatic hernia (CDH) is a structural birth defect characterized by a diaphragmatic defect, lung hypoplasia and structural vascular defects. In spite of recent developments, the pathogenesis of CDH is still poorly understood. CDH is a complex congenital disorder with multifactorial etiology consisting of genetic, cellular and mechanical factors. This review explores the cellular origin of CDH pathogenesis in the diaphragm and lungs and describes recent developments in basic and translational CDH research.

A case report of Potter’s syndrome in a newborn

Introduction. Potter’s sequence is a very rare and severe syndromic complex that includes congenital kidney defects leading to oligohydramnios, lung hypoplasia and structural skeletal disorders. Clinical case presentation: observation of a boy born from the 5th pregnancy to the mother at 37 weeks. Antenatally, the fetus was found to have bilateral renal and urinary bladder agenesis, malformations of the limbs, but the parents refused to terminate the pregnancy. After birth, the child was diagnosed with Potter’s syndrome with severe hypoplasia of the lungs, which required mechanical ventilation. In 2 hours after birth, the child developed a tension pneumothorax, which was arrested by performing drainage of the pleural cavity. During the day, the patient received complex treatment in the intensive care unit, despite which, by the 2nd day of life, the death of the child occurred. Currently, there are no guidelines for the treatment of Potter syndrome with proven positive long-term outcomes.Discussion. Children with Potter syndrome do not have the same set of symptoms, but they develop a chain of events leading to a common ultimate result - decreased amount of amniotic fluid. Abnormalities leading to oligohydramnios may include severe hypoplasia, dysplasia, polycystic, obstructive uropathy or renal agenesis. In most cases, the disease occurs sporadically, but there are also forms with transmission of the disorder through successive generations: autosomal dominant or recessive inheritance of polycystic disease, hereditary renal dysplasia caused by mutations in RET, UPK3A genes and other chromosomal abnormalities.Conclusion. Potter syndrome is a set of severe syndromes manifested by abnormalities in the development of kidneys, oligohydramnios, leading to lung hypoplasia, skeletal disorders and other congenital anomalies. The severity of congenital defects included in the set depends on the time periods when oligohydramnios occurred. Despite the availability of experimental therapies, the disease is now considered to be fatal.

Mice lacking DYRK2 exhibit congenital malformations with lung hypoplasia and altered Foxf1 expression gradient

Congenital malformations cause life-threatening diseases in pediatrics, yet the molecular mechanism of organogenesis is poorly understood. Here we show that Dyrk2-deficient mice display congenital malformations in multiple organs. Transcriptome analysis reveals molecular pathology of Dyrk2-deficient mice, particularly with respect to Foxf1 reduction. Mutant pups exhibit sudden death soon after birth due to respiratory failure. Detailed analyses of primordial lungs at the early developmental stage demonstrate that Dyrk2 deficiency leads to altered airway branching and insufficient alveolar development. Furthermore, the Foxf1 expression gradient in mutant lung mesenchyme is disrupted, reducing Foxf1 target genes, which are necessary for proper airway and alveolar development. In ex vivo lung culture system, we rescue the expression of Foxf1 and its target genes in Dyrk2-deficient lung by restoring Shh signaling activity. Taken together, we demonstrate that Dyrk2 is essential for embryogenesis and its disruption results in congenital malformation.

Genetics of diaphragmatic hernia

Congenital diaphragmatic hernia (CDH) is a life-threatening malformation characterised by failure of diaphragmatic development with lung hypoplasia and persistent pulmonary hypertension of the newborn (PPHN). The incidence is 1:2000 corresponding to 8% of all major congenital malformations. Morbidity and mortality in affected newborns are very high and at present, there is no precise prenatal or early postnatal prognostication parameter to predict clinical outcome in CDH patients. Most cases occur sporadically, however, genetic causes have long been discussed to explain a proportion of cases. These range from aneuploidy to complex chromosomal aberrations and specific mutations often causing a complex phenotype exhibiting multiple malformations along with CDH. This review summarises the genetic variations which have been observed in syndromic and isolated cases of congenital diaphragmatic hernia.

Increased circulating cytokeratin 19 fragment levels in preterm neonates receiving mechanical ventilation are associated with poor outcome

Invasive mechanical ventilation and oxygen toxicity are postnatal contributors to chronic lung disease of prematurity, also known as bronchopulmonary dysplasia (BPD). Cyfra 21-1 is a soluble fragment of cytokeratin 19, which belongs to the cytoskeleton stabilizing epithelial intermediate filaments. As a biomarker of structural integrity, Cyfra 21-1 might be associated with airway injury and lung hypoplasia in neonates. Serum Cyfra 21-1 concentrations for 80 preterm and 80 healthy term newborns were measured within 48 hours after birth. Preterm infants with the combined endpoint BPD/mortality had significantly higher Cyfra 21-1 levels compared to those without fulfilling BPD/mortality criteria (p=0.01). Also, severe RDS (>grade III) was associated with higher Cyfra levels (p=0.01). Total duration of oxygen therapy was more than five times longer in neonates with high Cyfra 21-1 levels (p=0.01). Infants with higher Cyfra 21-1 values were more likely to receive mechanical ventilation (50% vs. 17.5%). However the duration of mechanical ventilation was similar between groups. The median Cyfra value was 1.93 ng/ml (IQR: 1.68-2.53 ng/ml) in healthy term neonates and 8.5 ng/ml (IQR: 3.6-16.0 ng/ml) in preterm infants. Using ROC analysis, we calculated a Cyfra cutoff > 8.5 ng/ml to predict BPD/death with an AUC of 0.795 (p = 0.004), a sensitivity of 88.9% and a specificity of 55%. Mortality was predicted with a cutoff > 17.4 ng/ml (AUC: 0.94; p = 0.001), a sensitivity of 100% and a specificity of 84%. These findings suggest that Cyfra 21-1 concentration might be useful to predict poor outcome in premature infants.

Motion corrected fetal body MRI provides reliable 3D lung volumes in normal and abnormal fetuses

Objective:Evaluate deformable slice-to-volume registration (DSVR) to calculate 3D-segmented total lung volume (TLV) in fetuses with congenital diaphragmatic hernia, congenital lung lesions and healthy controls, with comparison to 2D-manual segmentation. Design:Pilot study Setting:Regional fetal medicine referral centre Sample:Fetal MRIs performed for clinical indications (abnormal cases) or as research participants (healthy controls) Methods:Sixteen MRI datasets of fetuses (22-32 weeks GA). Diagnosis: CDH(n=5), CPAM(n=2), CDH with BPS(n=1) and healthy control(n=8). DSVR was used for reconstruction of 3D isotropic (0.85 mm) volumes of fetal body followed by semi-automated lung segmentation. The resulting 3D TLV were compared to the traditional 2D-based volumetry, and a normogram of DSVR-derived fetal lung volumes from 100 cases was produced. Main Outcome Measures:Concordance with 2D-volumetry assessed with Bland-Altman analysis, results of segmentations presented visually. Observed/Expected values were calculated for abnormal cases based upon the normogram. Results:DSVR-derived TLV values have high correlation with the 2D-based measurements but with a consistently lower volume; bias -1.44cm3 [95% limits: -2.6 to -0.3] with improved resolution able to exclude hilar structures even in severe motion corruption or in cases of lung hypoplasia. Conclusions:Application of DSVR for fetal MRI provides a solution for analysis of motion corrupted scans and does not suffer from the interpolation error inherent in 2D-segmentation as per current clinical practice. It increases information content of acquired data in terms of visualising organs in 3D space and quantification of volumes, which we believe will have important value for counselling and surgical planning. Keywords:Fetal MRI; congenital diaphragmatic hernia; CPAM; lung volume

Congenital Diaphragmatic Hernia: More than Just a Lung Problem

Congenital Diaphragmatic Hernia (CDH) is a rare congenital anomaly characterized by a defect in the diaphragm, which permits abdominal organs to herniate into the thorax. This causes lung hypoplasia and at birth, children with CDH experience respiratory distress and pulmonary hypertension. Despite optimal neonatal treatment, CDH is still associated with a high mortality and morbidity. In severe cases, Fetal Intervention (FETO) may alter the natural course of this disease. Herein we describe the rationale, action mechanism and technique to perform this intervention. Despite hope giving results, this technique remains investigational for left sided CDH. However, an increased survival may come at the cost of increased morbidity. Children born with CDH are at increased risk for long and short-term morbidity, including neurodevelopmental problems. Until now, there are still uncertainties about the severity and prevalence of neurologic morbidity. Furthermore, it remains uncertain if these problems are already present prenatally and if a prenatal intervention influence this.