Telemedicine Versus Traditional In-Person Consultations: Comparison of Patient Satisfaction Rates.

Introduction: Data on patient satisfaction with the provision of genetic consultations using telemedicine are limited, especially those involving children. We compared patient satisfaction rates with telemedicine services versus traditional in-person encounters. Methods: A cross-sectional questionnaire-based study was conducted between January and June 2020. Questionnaires were distributed online to 1,672 consecutive patients who had received genetic counseling at our Genetics Institute in the clinical fields of adult and pediatric genetics, oncogenetics, and prenatal genetics, through in-person and/or telemedicine consultation. We used Likert scale with scores of 4-5 representing "satisfied"-"very satisfied" and 1-2 representing "very unsatisfied"-"unsatisfied." Results: The response rate was 27.3% (400 adults and 57 children <18 years), including 330 who had received in-person consultations (72.2%), 80 telemedicine consultations (17.5%), and 47 both consultations (10.3%). Mean satisfactory scores of 4-5 were reported by 82.1% in the in-person group versus 82.5% in the telemedicine group (p = 0.88). Mean scores of 1-2 were reported by 6.3% in the in-person group versus 11.2% in the telemedicine group (p = 0.31). No pediatric telemedicine group patient (n 12 = ) gave scores of 1-2 compared with 2/33 (6%) patients who had in-person pediatric consultations (p = 0.62). Most responders who had been counseled through telemedicine (n = 127, 84%) indicated willingness to use genetic services through telemedicine again. Conclusions: Users of genetic counseling through telemedicine, especially in the pediatric age group, were very satisfied at rates comparable to those of in-person consultations. Future research should evaluate patient compliance and views according to session type, information provided (e.g., diagnostic vs. negative results), and its nature (good vs. bad news).

A common benign intronic deletion masking a pathogenic deep intronic PCCB variant - genome sequencing and RNA studies to the rescue.

Propionic acidemia (PA) is an autosomal recessive metabolic disorder caused by variants in PCCA or PCCB, both sub-units of the propionyl-CoA carboxylase (PCC) enzyme. PCC is required for the catabolism of certain amino acids and odd-chain fatty acids. In its absence, the accumulated toxic metabolites cause metabolic acidosis, neurologic symptoms, multi-organ dysfunction and possible death. The clinical presentation of PA is highly variable, with typical onset in the neonatal or early infantile period. We encountered two families, whose children were diagnosed with PA. Exome sequencing (ES) failed to identify a pathogenic variant, and we proceeded with genome sequencing (GS), demonstrating homozygosity to a deep intronic PCCB variant. RNA analysis established that this variant creates a pseudoexon with a premature stop codon. The parents are variant carriers, though three of them display pseudo-homozygosity due to a common large benign intronic deletion on the second allele. The parental presumed homozygosity merits special attention, as it masked the causative variant at first, which was resolved only by RNA studies. Arriving at a rapid diagnosis, whether biochemical or genetic, can be crucial in directing lifesaving care, concluding the diagnostic odyssey, and allowing the family prenatal testing in subsequent pregnancies. This study demonstrates the power of integrative genetic studies in reaching a diagnosis, utilizing GS and RNA analysis to overcome ES limitations and define pathogenicity. Importantly, it highlights that intronic deletions should be taken into consideration when analyzing genomic data, so that pseudo-homozygosity would not be misinterpreted as true homozygosity, and pathogenic variants will not be mislabeled as benign.

Genetic diagnosis and detection rates using C9orf72 repeat expansion and a multi-gene panel in amyotrophic lateral sclerosis.

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disorder. It is mostly sporadic, with the C9orf72 repeat expansion being the most common genetic cause. While the prevalence of C9orf72-ALS in patients from different populations has been studied, data regarding the yield of C9orf72 compared to an ALS gene panel testing is limited.We aimed to explore the application of C9orf72 versus a gene panel in the general Israeli population. A total of 140 ALS patients attended our Neurogenetics Clinic throughout 2018-2023. Disease onset was between ages 60 and 69 years for most patients (34%); however, a quarter had an early-onset disease (< 50 years). Overall, 119 patients (85%) were genetically evaluated: 116 (97%) were tested for the C9orf72 repeat expansion and 64 (54%) underwent gene panel testing. The C9orf72 repeat expansion had a prevalence of 21% among Ashkenazi Jewish patients compared to 5.7% in non-Ashkenazi patients, while the gene panel had a higher yield in non-Ashkenazi patients with 14% disease-causing variants compared to 5.7% in Ashkenazi Jews. Among early-onset ALS patients, panel testing was positive in 12% compared to 2.9% for C9orf72.We suggest a testing strategy for the Israeli ALS patients: C9orf72 should be the first-tier test in Ashkenazi Jewish patients, while a gene panel should be considered as the first step in non-Ashkenazi and early-onset patients. Tiered testing has important implications for patient management, including prognosis, ongoing clinical trials, and prevention in future generations. Similar studies should be implemented worldwide to uncover the diverse ALS genetic architecture and facilitate tailored care.

Identification of 34 novel and 56 known FOXL2 mutations in patients with Blepharophimosis syndrome.

Blepharophimosis syndrome (BPES) is caused by loss-of-function mutations in the single-exon forkhead transcription factor gene FOXL2 and by genomic rearrangements of the FOXL2 locus. Here, we focus on 92 new intragenic FOXL2 mutations, 34 of which are novel. Specifically, we found 10 nonsense mutations (11%), 13 missense mutations (14%), 40 deletions or insertions leading to a frameshift (43%), and 29 in-frame changes (32%), of which 28 (30%) lead to a polyalanine expansion. This study confirms the existence of two previously described mutational hotspots. Moreover, we gained novel insights in genotype-phenotype correlations, emphasizing the need to interpret genotype-phenotype correlations individually and always in the context of further clinical observations.

Whole-exome sequencing in fetuses with central nervous system abnormalities.

OBJECTIVE: We describe our experience with whole-exome sequencing (WES) in fetuses with central nervous system (CNS) abnormalities following a normal chromosomal microarray result. METHODS: During the study period (2014-2017) 7 cases (9 fetuses) with prenatally diagnosed CNS abnormality, whose chromosomal microarray analysis was negative, were offered whole-exome sequencing analysis. RESULTS: A pathogenic or a likely pathogenic variant was found in 5 cases including a previously described, likely pathogenic de novo TUBA1A variant (Case #1); a previously described homozygous VRK1 variant (Case #2); an X-linked ARX variant (Case #3); a likely pathogenic heterozygous variant in the TUBB3 gene (Case #5). Finally, in two fetuses of the same couple (Case #6), a compound heterozygous state was detected, consisting of the NPHP1 gene deletion and a sequence variant of uncertain significance. Two additional cases had normal WES results. CONCLUSION: Whole-exome sequencing may improve prenatal diagnosis in fetuses with CNS abnormalities.

Clinical evaluation of isolated nonvisualized fetal gallbladder.

OBJECTIVE: Isolated nonvisualized fetal gallbladder (INVFGB) is relatively rare. In most cases, the gallbladder will eventually be detected. In some cases however, INVFGB may be associated with serious abnormalities, cystic fibrosis (CF), aneuploidy, and agenesis of the gall bladder. We describe a clinical evaluation of prenatally diagnosed INVFGB. METHODS: Cases of nonvisualized gallbladder were first evaluated by serial scans. Cases with no additional malformations were designated as INVFGB, and were further evaluated by mutation analysis for CF, and amniocentesis for karyotype and microvillar membrane enzymes (MME). RESULTS: A total of 22 cases of nonvisualized gallbladder were detected. Of these, 2 had additional malformations, and 3 were excluded because of incomplete evaluation. Of the remaining 17 cases, 3 (17.6%) had adverse outcomes: 1 case of CF, 1 case of 47,XXX, and 1 case of multiple congenital anomalies detected only postnatally. Abnormal levels of MMEs were detected in 3 cases, 1 of which was diagnosed with CF. In 2 cases, the gallbladder was not detected even after birth, but development is normal. CONCLUSION: Evaluation of INVFGB should include genetic counselling, amniocentesis for karyotype and MME analysis, CFTR mutation analysis and repeated ultrasound scans.

Prenatal diagnosis in Li-Fraumeni syndrome.

PURPOSE: The hallmark of Li-Fraumeni syndrome (LFS), a familial cancer syndrome, is constitutional TP53 mutation. The authors addressed the complex question of predictive prenatal genetic testing for cancer risk associated with inheritance of TP53 mutation. METHODS: A classic LFS family including the proband (a 20-month-old boy with rhabdomyosarcoma), his 36-year-old father with osteosarcoma, and his 40-year-old paternal aunt with bilateral breast cancer were identified as carriers of a TP53 germline mutation, a novel 1 base pair deletion in exon 5. A few years later, the mother became pregnant twice, and the parents requested prenatal diagnosis on each occasion. Genetic counseling, psychological evaluation, and support were provided by a multidisciplinary team including a pediatric oncologist, a geneticist, a psychosocial worker, a prenatal care provider, and an ethical representative. After providing overall information on LFS, including the high risk of developing secondary multiple neoplasms in LFS survivors, the committee approved prenatal diagnosis at the request of the family. RESULTS: In the two pregnancies, the two fetuses were found to be carriers of the same mutation. Nine years from diagnosis of the first tumor, the proband, and a month later his father, developed second tumors, multifocal osteosarcoma and leiomyosarcoma, respectively. CONCLUSIONS: Children with primary tumors belonging to LFS should be considered for screening for germline mutations and genetic counseling by a multidisciplinary team. Whether family members are found to be positive or negative as carriers, such measures may provide, by reducing uncertainty, psychological benefit to high-risk families.