Discriminating Power of Localized Three-Dimensional Facial Morphology

Hammond, Peter; Hutton, Tim J.; Allanson, Judith; Buxton, Bernard F.; Campbell, Linda E.; Clayton‐Smith, Jill; Donnai, Dian; Karmiloff‐Smith, Annette; Metcalfe, Kay; Murphy, K. C.; Patton, Michael A.; Pober, Barbara R.; Prescott, Katrina; Scambler, Peter J.; Shaw, Adam; Smith, Anne C.; Stevens, Angela; Temple, I. Karen; Hennekam, Raoul C. M.; Tassabehji, May

doi:10.1086/498396

Cited by 135 publications

(145 citation statements)

References 21 publications

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“…25,26 Previously, studies using 3D DSMs of face shape have delineated common facial features in a range of neurodevelopmental conditions, often, in addition, establishing accurate discriminating characteristics or assisting the determination of phenotype-genotype correlations. [26][27][28][29][30][31][32][33][34] We have shown that DSMbased analysis provides a very accurate instrument for classifying faces or facial regions along the control-WHS spectrum. In addition, for the first time, we have used DSMs to construct mean face surfaces matched for age and size for fine-grained analysis of six individuals, so that subtle face shape differences can be related to the underlying genotype.…”

Section: Wolf-hirschhorn Syndrome (Whs; Omim 194190) Is a Contiguous mentioning

confidence: 99%

“…30,40 DSM building and closest mean classification DSMs were constructed using techniques described elsewhere. 25,26 A DSM refers to the set of principal components (PCs) or principal component analysis (PCA) models accounting for the shape variation in the surfaces included. For a set of faces with wide age variation, the first mode of variation (PC1) follows the shape of a typical growth curve and is highly correlated with age.…”

Section: Image Preparationmentioning

confidence: 99%

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Fine-grained facial phenotype–genotype analysis in Wolf–Hirschhorn syndrome

Hammond¹,

Hannes

Suttie³

et al. 2011

Eur J Hum Genet

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Wolf-Hirschhorn syndrome is caused by anomalies of the short arm of chromosome 4. About 55% of cases are due to de novo terminal deletions, 40% from unbalanced translocations and 5% from other abnormalities. The facial phenotype is characterized by hypertelorism, protruding eyes, prominent glabella, broad nasal bridge and short philtrum. We used dense surface modelling and pattern recognition techniques to delineate the milder facial phenotype of individuals with a small terminal deletion (breakpoint within 4p16.3) compared to those with a large deletion (breakpoint more proximal than 4p16.3). Further, fine-grained facial analysis of several individuals with an atypical genotype and/or phenotype suggests that multiple genes contiguously contribute to the characteristic Wolf-Hirschhorn syndrome facial phenotype.

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Section: Wolf-hirschhorn Syndrome (Whs; Omim 194190) Is a Contiguous mentioning

confidence: 99%

Section: Image Preparationmentioning

confidence: 99%

Fine-grained facial phenotype–genotype analysis in Wolf–Hirschhorn syndrome

Hammond¹,

Hannes

Suttie³

et al. 2011

Eur J Hum Genet

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“…1,2 Using highly sensitive models of facial morphology, it has been possible to detect subtle differences in atypical patients and inform genotype-phenotype studies. 3,4 Advanced molecular genetic techniques have established increasingly detailed correlations between genotype and phenotype.…”

Section: Introductionmentioning

confidence: 99%

Face shape differs in phylogenetically related populations

Hopman

Merks

Suttie³

et al. 2014

Eur J Hum Genet

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3D analysis of facial morphology has delineated facial phenotypes in many medical conditions and detected fine grained differences between typical and atypical patients to inform genotype-phenotype studies. Next-generation sequencing techniques have enabled extremely detailed genotype-phenotype correlative analysis. Such comparisons typically employ control groups matched for age, sex and ethnicity and the distinction between ethnic categories in genotype-phenotype studies has been widely debated. The phylogenetic tree based on genetic polymorphism studies divides the world population into nine subpopulations. Here we show statistically significant face shape differences between two European Caucasian populations of close phylogenetic and geographic proximity from the UK and The Netherlands. The average face shape differences between the Dutch and UK cohorts were visualised in dynamic morphs and signature heat maps, and quantified for their statistical significance using both conventional anthropometry and state of the art dense surface modelling techniques. Our results demonstrate significant differences between Dutch and UK face shape. Other studies have shown that genetic variants influence normal facial variation. Thus, face shape difference between populations could reflect underlying genetic difference. This should be taken into account in genotype-phenotype studies and we recommend that in those studies reference groups be established in the same population as the individuals who form the subject of the study.

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“…12,13 At these higher levels of accuracy, less experienced clinicians may be encouraged to undertake appropriate genetic testing where it is available and there is uncertainty about the diagnosis. The dynamic and colour-coded visualizations of face-shape differences may be of use in clinical training.…”

Section: Discussionmentioning

confidence: 99%

Three-dimensional face shape in Fabry disease

et al. 2007

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Facial dysmorphology is an important feature in several lysosomal storage disorders. Although in Fabry disease facial dysmorphism is not a prominent sign, minor facial abnormalities have been previously reported. By analysing three-dimensional images of faces, we quantified facial dysmorphology in a cohort of both male and female Fabry patients. Morphometric analysis of different regions of the face revealed significant differences in face shape in male patients and to a lesser extent in female patients. In male patients, the most prominent abnormalities were located in the peri-orbital region. Pattern recognition techniques achieved a discrimination accuracy of up to 85% for male patients compared with healthy controls. The discrimination accuracy in female patients achieved only 67%. This objective method for facial dysmorphology assessment provided evidence for significant differences in face shape in both male and female Fabry patients compared with controls. However, because discrimination from healthy controls is too low, no key role in the diagnostic process can be expected.

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Discriminating Power of Localized Three-Dimensional Facial Morphology

Cited by 135 publications

References 21 publications

Fine-grained facial phenotype–genotype analysis in Wolf–Hirschhorn syndrome

Fine-grained facial phenotype–genotype analysis in Wolf–Hirschhorn syndrome

Face shape differs in phylogenetically related populations

Three-dimensional face shape in Fabry disease

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