Evaluation of an Interprofessional Oral Health Assessment Activity in Advanced Practice Nursing Education.

The curriculum for nurse practitioner (NP) students often overlooks the assessment of the oral cavity. In recognition of this, the HEENT (head, eyes, ears, nose, and throat) assessment was expanded to HEENOT (head, ears, eyes, nose, oral, and throat) through integration of an interprofessional educational (IPE) activity developed for University of Colorado NP and dental students. The aim of this study was to assess NP students' perceptions of an IPE activity in which dental faculty and students taught NP students how to conduct an oral exam, recognize oral health pathology, and apply fluoride varnish. Afterwards, the NP students completed an evaluation survey focusing on their thoughts, comfort level, organization, and understanding of the activity. This IPE activity was repeated over four semesters from 2014 to 2017, and significant differences among the semesters were compared. All NP students in the four semesters participated in the activity and the survey: semester one N=25, semester two N=31, semester three N=43, and semester four N=25. In all semesters, NP students reported feeling more confident conducting oral health exams after completion of the IPE activity. Semester four students agreed more with the idea of interprofessional collaboration (OR: 0.103) and receiving educational information not learned elsewhere in the curriculum (OR: 0.134) compared to semester one students. Higher odds for the session being well organized and conducted in a suitable time were found for semester four compared to semester two (OR: 0.217). These comparisons reflect improvement in teaching methodologies over the four semesters and an overall increased confidence for NP students in performing an oral health assessment.

Parental somatic mosaicism is underrecognized and influences recurrence risk of genomic disorders.

New human mutations are thought to originate in germ cells, thus making a recurrence of the same mutation in a sibling exceedingly rare. However, increasing sensitivity of genomic technologies has anecdotally revealed mosaicism for mutations in somatic tissues of apparently healthy parents. Such somatically mosaic parents might also have germline mosaicism that can potentially cause unexpected intergenerational recurrences. Here, we show that somatic mosaicism for transmitted mutations among parents of children with simplex genetic disease is more common than currently appreciated. Using the sensitivity of individual-specific breakpoint PCR, we prospectively screened 100 families with children affected by genomic disorders due to rare deletion copy-number variants (CNVs) determined to be de novo by clinical analysis of parental DNA. Surprisingly, we identified four cases of low-level somatic mosaicism for the transmitted CNV in DNA isolated from parental blood. Integrated probabilistic modeling of gametogenesis developed in response to our observations predicts that mutations in parental blood increase recurrence risk substantially more than parental mutations confined to the germline. Moreover, despite the fact that maternally transmitted mutations are the minority of alleles, our model suggests that sexual dimorphisms in gametogenesis result in a greater proportion of somatically mosaic transmitting mothers who are thus at increased risk of recurrence. Therefore, somatic mosaicism together with sexual differences in gametogenesis might explain a considerable fraction of unexpected recurrences of X-linked recessive disease. Overall, our results underscore an important role for somatic mosaicism and mitotic replicative mutational mechanisms in transmission genetics.

Co-occurrence of recurrent duplications of the DiGeorge syndrome region on both chromosome 22 homologues due to inherited and de novo events.

BACKGROUND: Genomic rearrangements usually involve one of the two chromosome homologues. Homozygous microdeletion/duplication is very rare. The chromosome 22q11.2 region is prone to recurrent rearrangements due to the presence of low-copy repeats. A common 3 Mb microdeletion causes the well-characterised DiGeorge syndrome (DGS). The reciprocal duplication is associated with an extremely variable phenotype, ranging from apparently normal to learning disabilities and multiple congenital anomalies. METHODS AND RESULTS: We describe duplications of the DGS region on both homologues in five patients from three families, detected by array CGH and confirmed by both fluorescence in situ hybridisation and single nucleotide polymorphism arrays. The proband in the first family is homozygous for the common duplication; one maternally inherited and the other a de novo duplication that was generated by nonallelic homologous recombination during spermatogenesis. The 22q11.2 duplications in the four individuals from the other two families are recurrent duplications on both homologues, one inherited from the mother and the other from the father. The phenotype in the patients with a 22q11.2 tetrasomy is similar to the features seen in duplication patients, including cognitive deficits and variable congenital defects. CONCLUSIONS: Our studies that reveal phenotypic variability in patients with four copies of the 22q11.2 genomic segment, demonstrate that both inherited and de novo events can result in the generation of homozygous duplications, and further document how multiple seemingly rare events can occur in a single individual.

19q13.11 cryptic deletion: description of two new cases and indication for a role of WTIP haploinsufficiency in hypospadias.

Developmental delay/intellectual disabilities, speech disturbance, pre- and postnatal growth retardation, microcephaly, signs of ectodermal dysplasia, and genital malformations in males (hypospadias) represent the phenotypic core of the recent emerging 19q13.11 deletion syndrome. Using array-CGH for genome-wide screening we detected an interstitial deletion of chromosome band 19q13.11 in two patients exhibiting the recognizable pattern of malformations as described in other instances of this submicroscopic genomic imbalance. The deletion detected in our patients has been compared with previously reported cases leading to the refinement of the minimal overlapping region (MOR) for this microdeletion syndrome to 324 kb. This region encompasses five genes: four zinc finger (ZNF) genes belonging to the KRAB-ZNF subfamily (ZNF302, ZNF181, ZNF599, and ZNF30) and LOC400685. On the basis of our male patient 1 and on further six male cases of the literature, we also highlighted that larger 19q13.11 deletions including the Wilms tumor interacting protein (WTIP) gene, proximal to the MOR, results in hypospadias making this gene a possible candidate for this genital abnormality due to its well-known interaction with WT1. Although the mechanism underlying the phenotypic effects of copy number alterations involving KRAB-ZNF genes at 19q13.11 has not clearly been established, we suggest their haploinsufficiency as the most likely candidate for the phenotypic core of the 19q13.11 deletion syndrome. In addition, we hypothesized WTIP gene haploinsufficiency as responsible for hypospadias.

Delineation of a deletion region critical for corpus callosal abnormalities in chromosome 1q43-q44.

Submicroscopic deletions involving chromosome 1q43-q44 result in cognitive impairment, microcephaly, growth restriction, dysmorphic features, and variable involvement of other organ systems. A consistently observed feature in patients with this deletion are the corpus callosal abnormalities (CCAs), ranging from thinning and hypoplasia to complete agenesis. Previous studies attempting to delineate the critical region for CCAs have yielded inconsistent results. We conducted a detailed clinical and molecular characterization of seven patients with deletions of chromosome 1q43-q44. Using array comparative genomic hybridization, we mapped the size, extent, and genomic content of these deletions. Four patients had CCAs, and shared the smallest region of overlap that contains only three protein coding genes, CEP170, SDCCAG8, and ZNF238. One patient with a small deletion involving SDCCAG8 and AKT3, and another patient with an intragenic deletion of AKT3 did not have any CCA, implying that the loss of these two genes is unlikely to be the cause of CCA. CEP170 is expressed extensively in the brain, and encodes for a protein that is a component of the centrosomal complex. ZNF238 is involved in control of neuronal progenitor cells and survival of cortical neurons. Our results rule out the involvement of AKT3, and implicate CEP170 and/or ZNF238 as novel genes causative for CCA in patients with a terminal 1q deletion.

Craniofacial and anthropometric phenotype in ankyloblepharon-ectodermal defects-cleft lip/palate syndrome (Hay-Wells syndrome) in a cohort of 17 patients.

Ankyloblepharon-ectodermal dysplasia-cleft lip/palate (AEC) syndrome and Rapp-Hodgkin syndrome are well-characterized clinical entities caused by mutations in the TP63 gene. While AEC and Rapp-Hodgkin had been thought to be clinically distinct entities, the elucidation of their molecular etiology confirmed that they are a clinical continuum as opposed to distinct disorders. We have evaluated 17 patients with AEC syndrome using a systematic clinical approach. In our study, we have identified new features and others that were thought to occur only rarely. These include short stature and poor weight gain with preservation of head circumference in nearly all subjects, trismus in 35% and hypospadias in 78% of males. In addition, we describe the frequency of phenotypic features and demonstrate the extreme clinical variability in the largest cohort of AEC individuals reported in the literature thus far.

Pre- and postnatal genetic testing by array-comparative genomic hybridization: genetic counseling perspectives.

Recently, a new genetic test has been developed that allows a more detailed examination of the genome when compared with a standard chromosome analysis. Array comparative genomic hybridization (CGH microarray; also known as chromosome microarray analysis) in effect, combines chromosome and fluorescence in situ hybridization analyses allowing detection not only of aneuploidies, but also of all known microdeletion and microduplication disorders, including telomere rearrangements. Since 2004, this testing has been available in the Medical Genetics Laboratory at Baylor College of Medicine for postnatal evaluation and diagnosis of individuals with suspected genomic disorders. Subsequently, to assess the feasibility of offering CGH microarray for prenatal diagnosis, a prospective study was conducted on 98 pregnancies in a clinical setting comparing the results obtained from array CGH with those obtained from a standard karyotype. This was followed by the availability of prenatal testing on a clinical basis in 2005. To date, we have analyzed over 8000 cases referred to our clinical laboratory, including approximately 300 prenatal cases. With the clinical introduction of any new testing strategy, and particularly one focused on genetic disorders, issues of patient education, result interpretation, and genetic counseling must be anticipated and strategies adopted to allow the implementation of the testing with maximum benefit and minimum risk. In this article, we describe our experience with over 8000 clinical prenatal and postnatal cases of CGH microarray ordered by our clinical service or referred to the Baylor Medical Genetics Laboratory and describe the strategies used to optimize patient and provider education, facilitate clinical interpretation of results, and provide counseling for unique clinical circumstances.

Isolated mitochondrial myopathy associated with muscle coenzyme Q10 deficiency.

BACKGROUND: Primary coenzyme Q(10) (CoQ(10)) deficiency is rare. The encephalomyopathic form, described in few families, is characterized by exercise intolerance, recurrent myoglobinuria, developmental delay, ataxia, and seizures. OBJECTIVE: To report a rare manifestation of CoQ(10) deficiency with isolated mitochondrial myopathy without central nervous system involvement. METHODS: The patient was evaluated for progressive muscle weakness. Comprehensive clinical evaluation and muscle biopsy were performed for histopathologic analysis and mitochondrial DNA and respiratory chain enzyme studies. The patient began taking 150 mg/d of a CoQ(10) supplement. RESULTS: The elevated creatine kinase and lactate levels with abnormal urine organic acid and acylcarnitine profiles in this patient suggested a mitochondrial disorder. Skeletal muscle histochemical evaluation revealed ragged red fibers, and respiratory chain enzyme analyses showed partial reductions in complex I, I + III, and II + III activities with greater than 200% of normal citrate synthase activity. The CoQ(10) concentration in skeletal muscle was 46% of the normal reference mean. The in vitro addition of 50 micromol/L of coenzyme Q(1) to the succinate cytochrome-c reductase assay of the patient's skeletal muscle whole homogenate increased the succinate cytochrome-c reductase activity 8-fold compared with 2.8-fold in the normal control homogenates. Follow-up of the patient in 6 months demonstrated significant clinical improvement with normalization of creatine kinase and lactate levels. CONCLUSIONS: The absence of central nervous system involvement and recurrent myoglobinuria expands the clinical phenotype of this treatable mitochondrial disorder. The complete recovery of myopathy with exogenous CoQ(10) supplementation observed in this patient highlights the importance of early identification and treatment of this genetic disorder.

X-linked Menkes disease: first documented report of germ-line mosaicism.

This work investigated a three-generation Menkes disease family, where germ-line mosaicism was suspected in the maternal grandmother of the index patient. She had given birth to 2 boys who died of suspected Menkes disease on the basis of clinical and photographic evidence. Biochemical analysis of the index patient confirmed the diagnosis of Menkes disease, and DNA analysis established a partial gene deletion (EX11_EX23del), involving exons 11-23 and the 3'-untranslated region (UTR) of ATP7A. A junction fragment was detectable by Southern blot analysis, which enabled carrier analysis. The mother was demonstrated to be a carrier, whereas analysis of lymphoblasts and skin fibroblasts from the maternal grandmother gave no indication of a partial gene deletion. No materials were available from the possibly affected maternal uncles. Further genetic analyses, including biochemical testing of the grandmother and haplotype analysis using four intragenic markers on DNA from selected members of the family, corroborated this finding. The combined results from DNA analyses showed that the grandmother had transmitted three different ATP7A haplotypes to her offspring: (1) the at-risk allele (CA(B))-1 and the deletion; (2) the at-risk allele (CA(B))-1 without deletion; and (3) the second allele (CAB)-2 without deletion. In conclusion, our study demonstrated segregation of Menkes disease within the family investigated that can best be explained by extensive germ-line mosaicism in the maternal grandmother. The finding of germ-line mosaicism has obvious implications for genetic counseling of Menkes disease families.

A general approach to genetic counseling.

Genetic counseling can best be performed if a systematic approach is taken. The geneticist or genetic counselor has the difficult task of conveying complex information to patients in an understandable form. At the same time, this must be done in a nondirective manner, affording the patient the right to make his or her own decisions. Obtaining accurate family and medical history information is crucial to the genetic counseling process. Given the nature of genetic information, multiple sessions may be necessary to ensure that the patient understands the risks involved in his or her particular situation.