Outcomes and Predictors of Perinatal Mortality in Fetuses With Ebstein Anomaly or Tricuspid Valve Dysplasia in the Current Era
Background-Ebstein anomaly and tricuspid valve dysplasia are rare congenital tricuspid valve malformations associated with high perinatal mortality. The literature consists of small, single-center case series spanning several decades. We performed a multicenter study to assess the outcomes and factors associated with mortality after fetal diagnosis in the current era. Methods and Results-Fetuses diagnosed with Ebstein anomaly and tricuspid valve dysplasia from 2005 to 2011 wereincluded from 23 centers. The primary outcome was perinatal mortality, defined as fetal demise or death before neonatal discharge. Of 243 fetuses diagnosed at a mean gestational age of 27±6 weeks, there were 11 lost to follow-up (5%), 15 terminations (6%), and 41 demises (17%). In the live-born cohort of 176 live-born patients, 56 (32%) died before discharge, yielding an overall perinatal mortality of 45%. Independent predictors of mortality at the time of diagnosis were gestational age <32 weeks (odds ratio, 8.6; 95% confidence interval, 3.5-21.0; P<0.001), tricuspid valve annulus diameter z-score (odds ratio, 1.3; 95% confidence interval, 1.1-1.5; P<0.001), pulmonary regurgitation (odds ratio, 2.9; 95% confidence interval, 1.4-6.2; P<0.001), and a pericardial effusion (odds ratio, 2.5; 95% confidence interval, 1.1-6.0;© 2015 American Heart Association, Inc.Circulation characterized by apical displacement of the valve or leaflet deformation, respectively. 3 In severe cases of dysplasia, the tricuspid valve orifice may become unguarded. 4,5 Although there is a broad morphologic spectrum, these malformations lead to the same hemodynamic burden, namely, tricuspid regurgitation (TR) and its pathophysiological sequelae. Although older children and adults with EA/TVD may be asymptomatic for years, the diagnosis of EA/TVD in the perinatal period carries a poor prognosis. In the fetus, severe TR may lead to cardiomegaly, hydrops, and arrhythmia, with demise rates as high as 48%.6 Among prenatally diagnosed patients who survive to live birth, hemodynamic instability, cyanosis, and respiratory compromise are common. Although neonatal mortality approached 80 to 85% in early series, 7,8 various single-center series have reported reduced mortality in the past 2 decades, ranging from 17% to 56%. 9-12 Clinical Perspective on p 489Fetal risk factors for perinatal mortality have been identified, including lack of antegrade flow across the pulmonary valve and retrograde duct flow 9-12 and fetal distress. 12However, studies were limited by small sample sizes, with Yu et al 12 reporting the largest series to date with 46 prenatally diagnosed patients. The prognostic value of indices of cardiomegaly, such as the cardiothoracic area (CTA) ratio and the right atrial area index, has been mixed. [9][10][11][12][13] Importantly, hemodynamic factors with potentially important influences on perinatal mortality, such as right ventricular pressure and the presence of pulmonary regurgitation (PR), have not been investigated.Since our understanding of fetuses diagnose...
We describe the contents of the IFCIR and present post-natal data to suggest potential benefit to fetal therapy among pregnancies considered for possible intervention and support proposals for additional work.
Fewer deaths occurred in neonates with prenatal detection of their critical CHD requiring ENCI. However, there was no statistical difference in survival demonstrated for prenatally diagnosed neonates in this small cohort. Prenatal detection did improve preoperative clinical status and shorten hospital length of stay.
We report the cloning of the gene encoding a 36-kDa leptospiral outer membrane lipoprotein, designated LipL36. We obtained the N-terminal amino acid sequence of a staphylococcal V8 proteolytic-digest fragment in order to design an oligonucleotide probe. A Lambda-Zap II library containing EcoRI fragments of Leptospira kirschneri DNA was screened, and a 2.3-kb DNA fragment which contained the entire structural lipL36 gene was identified. Several lines of evidence indicate that LipL36 is lipid modified in a manner similar to that of LipL41, a leptospiral outer membrane lipoprotein we described in a previous study (E. S. Shang, T. A. Summers, and D. A. Haake, Infect. Immun. 64:2322–2330, 1996). The deduced amino acid sequence of LipL36 would constitute a 364-amino-acid polypeptide with a 20-amino-acid signal peptide, followed by an L-X-Y-C lipoprotein signal peptidase cleavage site. LipL36 is solubilized by Triton X-114 extraction of L. kirschneri; phase separation results in partitioning of LipL36 exclusively into the hydrophobic, detergent phase. LipL36 is intrinsically labeled during incubation of L. kirschneri in media containing [3H]palmitate. Processing of LipL36 is inhibited by globomycin, a selective inhibitor of lipoprotein signal peptidase. After processing, LipL36 is exported to the outer membrane along with LipL41 and lipopolysaccharide. Unlike LipL41, there appears to be differential expression of LipL36. In early-log-phase cultures, LipL36 is one of the most abundant L. kirschneri proteins. However, LipL36 levels drop considerably beginning in mid-log phase. LipL36 expression in vivo was evaluated by examining the humoral immune response to leptospiral antigens in the hamster model of leptospirosis. Hamsters surviving challenge with culture-adapted virulent L. kirschneri generate a strong antibody response to LipL36. In contrast, sera from hamsters surviving challenge with host-adaptedL. kirschneri do not recognize LipL36. These findings suggest that LipL36 expression is downregulated during mammalian infection, providing a marker for studying the mechanisms by which pathogenic Leptospira species adapt to the host environment.
Background and Purpose Abnormal cerebral microstructure has been documented in term neonates with congenital heart disease (CHD) portending risk for injury and poor neurodevelopmental outcome. Our hypothesis was that preterm neonates with CHD would demonstrate diffuse cerebral microstructural abnormalities when compared to critically ill neonates without CHD. A secondary aim was to identify any association between microstructural abnormalities, white matter injury (e.g., punctate white matter lesions, pWMLs) and other clinical variables, including heart lesion. Material and Methods Using Tract-Based-Spatial-Statistics (TBSS), an unbiased, voxel-wise method for analyzing diffusion tensor imaging data, we compared 21 preterm neonates with CHD to two cohorts of neonates without CHD: 28 term and 27 preterm neonates, identified from the same neonatal intensive care unit. Results Compared to term neonates without CHD, preterm neonates with CHD had microstructural abnormalities in widespread regions of the central white matter. However, 42% of the preterm CHD neonates had pWMLs. When neonates with pWMLs were excluded, microstructural abnormalities remained only in the splenium. Preterms with CHD had similar microstructure to preterms without CHD. Conclusion Diffuse microstructural abnormalities were observed in preterm neonates with CHD, strongly associated with pWMLs. Independently, regional vulnerability of the splenium, a structure associated with visual spatial function, was observed in all preterm CHD neonates.
Fetoscopic Laser Photocoagulation of Feeding Vessels to a Large Placental Chorioangioma following Fetal Deterioration after Amnioreduction
Large placental chorioangiomas (>4 cm) can precipitate severe polyhydramnios, fetal anemia, growth restriction, high-output cardiac failure, hydrops, and fetal demise. We report a case of a large chorioangioma that was treated in a stepwise fashion with amnioreduction to ameliorate maternal discomfort, followed by fetoscopic laser ablation of the feeding vessels after rapid evolution of heart failure. Although amnioreduction was helpful in improving maternal symptoms, we suspect that the drop in intrauterine pressure from the amniotic fluid decompression may have resulted in increased tumor perfusion, thereby promoting fetal deterioration due to a ‘steal’ phenomenon. Close scrutiny of the fetal status via ultrasound is required, particularly if amnioreduction is necessary, and definitive treatment should be considered once early signs of heart failure develop. Fetoscopic laser ablation of the feeding vessels is a feasible definitive treatment of a large chorioangioma in cases in which perfusion of the tumor is via a superficial nonterminus umbilical artery. Future reports should describe the anatomy of the blood supply to the chorioangioma, in the hopes that further guidelines for surgical candidacy may be established.
Infants born with congenital heart disease (CHD) may require emergent treatment in the newborn period. These infants are likely to benefit the most from a prenatal diagnosis, which allows for optimal perinatal planning. Several cardiac centers have created guidelines for the management of these high-risk patients with CHD. This paper will review and compare several prenatal CHD classification systems with a particular focus on the most critical forms of CHD in the fetus and newborn. A contemporary definition of critical CHD is one which requires urgent intervention in the first 24 h of life to prevent death. Such cardiac interventions may be not only life saving for the infant but also decrease subsequent morbidity. Critical CHD cases may require delivery at specialized centers that can provide perinatal, obstetric, cardiology and cardiothoracic surgery care. Fetuses diagnosed in mid-gestation require detailed fetal diagnostics and serial monitoring during the prenatal period, in order to assess for ongoing changes and identify progression to a more severe cardiac status. Critical CHD may progress in utero and there is still much to be learned about how to best predict those who will require urgent neonatal interventions. Despite improved therapeutic capabilities, newborns with critical CHD continue to have significant morbidity and mortality due to compromise that begins in the delivery room. Fetal echocardiography is the best way to predict the need for specialized care at birth to improve outcome. Once the diagnosis is made of critical CHD, delivery at the proper time and in appropriate institution with specific care protocols should be initiated. More work needs to be done to better delineate the risk factors for progression of critical CHD and to determine which newborns will require specialized care. The most frequently described forms of critical CHD requiring immediate intervention include hypoplastic left heart syndrome with intact or severely restricted atrial septum, obstructed total anomalous pulmonary venous return and transposition of the great arteries with restrictive atrial septum.
Fetal echocardiography facilitates the prenatal diagnosis of infants with congenital heart disease (CHD) and through sequential examinations, allows assessment of fetal hemodynamics and cardiovascular status from the time of diagnosis to delivery. Fetal cardiologists have created diagnostic protocols aimed at risk stratifying severity and potential postnatal compromise in fetuses with CHD, and identifying those who may require special intervention at birth or within the first days of life. In this article, we review fetal cardiovascular physiology, the progression of CHD in utero and fetal echocardiographic findings used for risk stratification of newborns with CHD, as well as some of the basic principles of planning for the neonatal resuscitation and initial transitional care of these complex newborns.
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