The value of detailed first-trimester ultrasound in the era of noninvasive prenatal testing.

BACKGROUND: In 2020, the American College of Obstetricians and Gynecologists recommended noninvasive prenatal testing be offered to all patients. However, current societal guidelines in the United States do not universally recommend a detailed first-trimester ultrasound. OBJECTIVE: This study aimed to determine the additional findings identified through first-trimester ultrasound that would have otherwise been missed if noninvasive prenatal testing was used alone as a first-trimester screening method. STUDY DESIGN: This was a retrospective cohort study involving 2158 pregnant patients and 2216 fetuses that were seen at a single medical center between January 1, 2020, and December 31, 2022. All those included underwent both noninvasive prenatal testing and detailed first-trimester ultrasound between 11.0 and 13.6 weeks of gestation. Noninvasive prenatal testing results were categorized as low risk or high risk, and first-trimester ultrasound results were categorized as normal or abnormal. Abnormal first-trimester ultrasounds were further classified as first-trimester screening markers (increased nuchal translucency, absent nasal bone, tricuspid regurgitation, and ductus venosus reverse a-wave) or structural defects (the cranium, neck, heart, thorax, abdominal wall, stomach, kidneys, bladder, spine, and extremities). Descriptive statistics were used to report our findings. RESULTS: Of 2216 fetuses, 65 (3.0%) had a high-risk noninvasive prenatal testing result, whereas 2151 (97.0%) had a low-risk noninvasive prenatal testing result. Of those with a low-risk noninvasive prenatal testing result, 2035 (94.6%) had a normal first-trimester ultrasound, whereas 116 (5.4%) had at least 1 abnormal finding on first-trimester ultrasound. The most common screening marker detected within the low-risk noninvasive prenatal testing group was absent nasal bone (52/2151 [2.4%]), followed by reversed a-wave of the ductus venosus (30/2151 [1.4%]). The most common structural defect in this group was cardiac abnormality (15/2151 [0.7%]). Overall, 181 fetuses were identified as having "abnormal screening" through either a high-risk noninvasive prenatal testing result (n=65) or through a low-risk noninvasive prenatal testing result but abnormal first-trimester ultrasound (n=116). In summary, the incorporation of first-trimester ultrasound screening identified 116 additional fetuses (5.4%) that required further follow-up and surveillance than noninvasive prenatal testing alone would have identified. CONCLUSION: Detailed first-trimester ultrasound identified more fetuses with a potential abnormality than noninvasive prenatal testing alone. Therefore, first-trimester ultrasound remains a valuable screening method that should be used in combination with noninvasive prenatal testing.

Third Trimester Ultrasound Stratifies Risk of Peripartum Complications in Pregnancies Complicated by Impaired Glucose Tolerance.

OBJECTIVE: The objective of our study was to investigate the effect of impaired glucose metabolism (IGM) and ultrasound (US) findings consistent with hyperglycemia on maternal and neonatal outcomes. STUDY DESIGN: This was a retrospective case-control study of singleton, nonanomalous pregnancies with an elevated 1-hour glucose screening test (GST) completed after 23 weeks of gestation. IGM was defined as a 1-hour GST of >130, but less than two abnormal values on 3-hour glucose tolerance test (GTT). Gestational diabetes was defined as two or more abnormal values on 3-hour GTT. Ultrasound evidence of hyperglycemia was defined as abdominal circumference >95th centile and/or polyhydramnios. Individuals with IGM were divided into those with ultrasound evidence of hyperglycemia (impaired glucose metabolism consistent with ultrasound findings [IGM-US]) and those without IGM. Maternal demographics, delivery outcomes (gestational age at delivery, delivery mode, shoulder dystocia, lacerations), postpartum hemorrhage, and neonatal outcome (birth weight centile [BW%], neonatal intensive care unit admission, hypoglycemia, and glucose) were recorded. Composite morbidity was tabulated. Delivery and neonatal outcome variables were compared in individuals with IGM-US, IGM, and gestational diabetes mellitus (GDM). Odds ratios were calculated and adjusted for maternal age, BMI, and gestational weight gain. RESULTS: A total of 637 individuals with an abnormal 1-hour GST were included (122 with IGM-US, 280 with IGM, and 235 with GDM). When compared to the IGM group, IGM-US had higher rates of cesarean delivery and BW% > 90th centile at delivery (adjusted odds ratio [aOR]: 1.7 [1.1-2.8] and aOR: 5.9 [2.7-13.0], respectively). Individuals with GDM also demonstrated similar rates with BW% > 90% but not cesarean section(aOR: 3.9 [1.8-8.5] and aOR: 1.4 [0.9-2.1], respectively). The remaining maternal and fetal outcomes were similar. CONCLUSION: Women with impaired glucose tolerance should have a third-trimester ultrasound to identify an increased risk of perinatal complications. KEY POINTS: · Women with elevated blood glucose screening should be evaluated with third-trimester ultrasound to identify risks for perinatal morbidity.. · The third-trimester ultrasound identifies individuals at risk for cesarean section.. · Counseling should be completed with individuals with polyhydramnios or accelerated growth..

Granulocyte-macrophage colony-stimulating factor initiates amniotic membrane rupture and preterm birth in a mouse model.

OBJECTIVE: Preterm premature rupture of membranes is associated with 30% of all preterm births. The weakening of amniotic membranes is associated with an increase in matrix metallopeptidases (MMPs) along with a decrease in their inhibitors, tissue inhibitor metallopeptidases (TIMPs). Additionally, granulocyte-macrophage colony-stimulating factor (GM-CSF) has been shown to weaken fetal membranes in-vitro. We hypothesize pregnant mice treated with GM-CSF lead to increased MMPs:TIMPs resulting in membrane rupture and preterm birth. STUDY DESIGN: Pregnant CD-1 mice on gestational day 17 received either an intrauterine injection of GM-CSF or vehicle control. A second series of mice were administered an intrauterine injection of Lipopolysaccharide along with either anti-mouse GM-CSF or control antibody. Mice were evaluated for rupture of membranes and/or preterm birth and the uterus, amniotic fluid, and serum were collected for analysis. RESULTS: 87.5% of GM-CSF mice exhibited evidence of membrane rupture or preterm birth, compared with 0% in control mice (p < .001). Treatment with GM-CSF decreased the expression of TNFα (p < .05) while increasing the ratio of MMP2:TIMP1 (p < .05), MMP2:TIMP2 (p < .05), MMP2:TIMP3 (p < .001), MMP9:TIMP1 (p < .01), MMP9:TIMP2 (p < .05), MMP9:TIMP3 (p < .001), and MMP10:TIMP1 (p < .05). Mice treated with LPS and the GM-CSF antibody resulted in a decrease in the ratio of MMP2:TIMP1 (p < .0001) compared with controls. CONCLUSION: These studies demonstrate GM-CSF will result in membrane rupture and preterm birth by increasing the ratio MMPs:TIMPs in our animal model. By increasing our understanding of the molecular pathways associated with GM-CSF, we may be able to develop future therapies to prevent preterm birth and reduce neonatal morbidity.

Whole exome sequencing identifies RAI1 mutation in a morbidly obese child diagnosed with ROHHAD syndrome.

CONTEXT: The current obesity epidemic is attributed to complex interactions between genetic and environmental factors. However, a limited number of cases, especially those with early-onset severe obesity, are linked to single gene defects. Rapid-onset obesity with hypothalamic dysfunction, hypoventilation and autonomic dysregulation (ROHHAD) is one of the syndromes that presents with abrupt-onset extreme weight gain with an unknown genetic basis. OBJECTIVE: To identify the underlying genetic etiology in a child with morbid early-onset obesity, hypoventilation, and autonomic and behavioral disturbances who was clinically diagnosed with ROHHAD syndrome. Design/Setting/Intervention: The index patient was evaluated at an academic medical center. Whole-exome sequencing was performed on the proband and his parents. Genetic variants were validated by Sanger sequencing. RESULTS: We identified a novel de novo nonsense mutation, c.3265 C>T (p.R1089X), in the retinoic acid-induced 1 (RAI1) gene in the proband. Mutations in the RAI1 gene are known to cause Smith-Magenis syndrome (SMS). On further evaluation, his clinical features were not typical of either SMS or ROHHAD syndrome. CONCLUSIONS: This study identifies a de novo RAI1 mutation in a child with morbid obesity and a clinical diagnosis of ROHHAD syndrome. Although extreme early-onset obesity, autonomic disturbances, and hypoventilation are present in ROHHAD, several of the clinical findings are consistent with SMS. This case highlights the challenges in the diagnosis of ROHHAD syndrome and its potential overlap with SMS. We also propose RAI1 as a candidate gene for children with morbid obesity.

A compound heterozygous mutation in GPD1 causes hepatomegaly, steatohepatitis, and hypertriglyceridemia.

The constellation of clinico-pathological and laboratory findings including massive hepatomegaly, steatosis, and marked hypertriglyceridemia in infancy is extremely rare. We describe a child who is presented with the above findings, and despite extensive diagnostic testing no cause could be identified. Whole exome sequencing was performed on the patient and parents' DNA. Mutations in GPD1 encoding glycerol-3-phosphate dehydrogenase that catalyzes the reversible redox reaction of dihydroxyacetone phosphate and NADH to glycerol-3-phosphate (G3P) and NAD(+) were identified. The proband inherited a GPD1 deletion from the father determined using copy number analysis and a missense change p.(R229Q) from the mother. GPD1 protein was absent in the patient's liver biopsy on western blot. Low normal activity of carnitine palmitoyl transferases, CPT1 and CPT2, was present in the patient's skin fibroblasts, without mutations in genes encoding for these proteins. This is the first report of compound heterozygous mutations in GPD1 associated with a lack of GPD1 protein and reduction in CPT1 and CPT2 activity.