Your search keyword '"Barton, Stephanie"' showing total 4 results

1. Additional file 2 of Recommendations for clinical interpretation of variants found in non-coding regions of the genome

Author

Ellingford, Jamie M., Ahn, Joo Wook, Bagnall, Richard D., Baralle, Diana, Barton, Stephanie, Campbell, Chris, Downes, Kate, Ellard, Sian, Duff-Farrier, Celia, FitzPatrick, David R., Greally, John M., Ingles, Jodie, Krishnan, Neesha, Lord, Jenny, Martin, Hilary C., Newman, William G., O’Donnell-Luria, Anne, Ramsden, Simon C., Rehm, Heidi L., Richardson, Ebony, Singer-Berk, Moriel, Taylor, Jenny C., Williams, Maggie, Wood, Jordan C., Wright, Caroline F., Harrison, Steven M., and Whiffin, Nicola

Abstract

Additional file 2: Fig S1. Identifying regulatory variants in trans with pLoF variants in GEL.

Published

2022

2. Assessment of the incorporation of CNV surveillance into gene panel next-generation sequencing testing for inherited retinal diseases

Author

Ellingford, Jamie M, Horn, Bradley, Campbell, Christopher, Arno, Gavin, Barton, Stephanie, Tate, Catriona, Bhaskar, Sanjeev, Sergouniotis, Panagiotis I, Taylor, Rachel L, Carss, Keren J, Raymond, Lucy FL, Michaelides, Michel, Ramsden, Simon C, Webster, Andrew R, Black, Graeme CM, Ellingford, Jamie M [0000-0003-1137-9768], and Apollo - University of Cambridge Repository

Subjects

DNA Copy Number Variations, High-Throughput Nucleotide Sequencing, Membrane Proteins, Ribonucleoproteins, Small Nuclear, Workflow, Cytoskeletal Proteins, copy-number variation, Gene Frequency, inherited retinal disease, Gene Duplication, parasitic diseases, molecular genetics, Retinal Dystrophies, Humans, next-generation sequencing, Genetic Predisposition to Disease, Algorithms, Adaptor Proteins, Signal Transducing

Abstract

Background Diagnostic use of gene panel next-generation sequencing (NGS) techniques is commonplace for individuals with inherited retinal dystrophies (IRDs), a highly genetically heterogeneous group of disorders. However, these techniques have often failed to capture the complete spectrum of genomic variation causing IRD, including CNVs. This study assessed the applicability of introducing CNV surveillance into first-tier diagnostic gene panel NGS services for IRD. Methods Three read-depth algorithms were applied to gene panel NGS data sets for 550 referred individuals, and informatics strategies used for quality assurance and CNV filtering. CNV events were confirmed and reported to referring clinicians through an accredited diagnostic laboratory. Results We confirmed the presence of 33 deletions and 11 duplications, determining these findings to contribute to the confirmed or provisional molecular diagnosis of IRD for 25 individuals. We show that at least 7% of individuals referred for diagnostic testing for IRD have a CNV within genes relevant to their clinical diagnosis, and determined a positive predictive value of 79% for the employed CNV filtering techniques. Conclusion Incorporation of CNV analysis increases diagnostic yield of gene panel NGS diagnostic tests for IRD, increases clarity in diagnostic reporting and expands the spectrum of known disease-causing mutations.

Published

2018

3. Additional file 1: of The role of small in-frame insertions/deletions in inherited eye disorders and how structural modelling can help estimate their pathogenicity

Author

Sergouniotis, Panagiotis, Barton, Stephanie, Waller, Sarah, Rahat Perveen, Ellingford, Jamie, Campbell, Christopher, Hall, Georgina, Gillespie, Rachel, Bhaskar, Sanjeev, Ramsden, Simon, Black, Graeme, and Lovell, Simon

Abstract

Table S1. Genes and transcripts included in multigene panel tests for retinal dystrophy and childhood cataracts. Table S2. Clinical and in silico evaluation of small (⠤21 nucleotides) in-frame insertions/deletions identified by panel-based genetic diagnostic testing in 486 probands with retinal dystrophy and 181 probands with childhood cataract. Table S3. Previously reported disease-associated small in-frame insertions/deletions in genes found to have clinically reported variants in the present study. (PDF 241 kb)

Published

2016

4. Four Weeks of Minimalist Style Running Training Reduced Lumbar Paraspinal Muscle Activation during Shod Running

Author

Barton, Stephanie, Brown, David, and Joyce, Talia

Abstract

Background and Purpose: Research has shown that the risk of low back dysfunctions in runners is related to the increased mileage of distance running. Repetitive shock loading of the spinal structures during running has been indicated as one of the important biomechanical mechanisms underlying such injury. Acute changes in foot strike pattern, like those seen during minimalist style running, have been shown to lead to modifications in lumbar range of motion. Minimalist style running could lead to changes in lumbar biomechanics and muscle activation, potentially reducing the loading on the musculoskeletal structures of the lower back. However, the long term effects of minimalist style running on lumbar biomechanics have not been evaluated. The purpose of this study was to investigate the effects a 4-week training program aimed at transitioning recreational runners to minimalist style footwear would have on lower back kinematics and lumbar paraspinal muscle activation. Subjects: 17 volunteers between the ages of 18-45 years who were habitually shod runners and averaged running 10-50 km per week participated in the study. Data from 15 volunteers was used in the analysis of the biomechanics. Inclusion and exclusion criteria were used to determine the appropriateness of each volunteer for this study. Methods: Subjects participated in three data collection sessions at the beginning, during (2-week), and at the end of a 4-week training program. The training consists of progressively increasing the distance each runner ran in the minimalist shoes up to 30-50% of their regular running distance while maintaining the overall distance (minimalist + normal shoes) comparable to before training. Running trials were collected with the subject wearing their normal running shoes. Subjects were asked to run at a prescribed speed (11.2 km/h), and a blinded self-selected speed. During running, kinematics of the lower back in the sagittal plane was recorded using an electro-goniometer. Surface EMG was used to monitor the activation of the lower back (L3 level) paraspinal muscles. Data collected during 10 stance phases were averaged and used for analysis. One-way repeated measures ANOVA tests were used to analyze the effect of training on lumbar kinematics and lumbar paraspinal muscle activation. Results: For the 11.2 km/h running speed, statistically significant differences were found in mean lower back posture (PRE = 1.9 ± 15.3 degrees, MID = 0.4 ± 13.0 degrees, POST = -6.0 ± 13.3 degrees, p = 0.001) and contralateral lumbar paraspinal muscle activation (PRE = 47.0 ± 34.0%, MID = 24.9 ± 8.2%, POST = 29.4 ± 11.3%, p = 0.039) after training. For the self-selected running speed, statistically significant differences were found in mean lower back posture (PRE = 2.3 ± 15.5 degrees, MID = 0.9 ± 13.9 degrees, POST = -5.7 ± 14.2 degrees, p = 0.002) and contralateral lumbar paraspinal muscle activation (PRE = 41.6 ± 28.6%, MID = 23.4 ± 6.2%, POST = 30.3 ± 11.6%, p = 0.047) after training. During both speeds, lower back posture became more extended and contralateral lumbar paraspinal muscle activation decreased. No significant differences were noted in overall lower back range of motion or ipsilateral paraspinal muscle activation over the training period at either speed. Conclusions: Including minimalist running shoes and barefoot exercises into a runners' training regime can alter the lumbar spinal kinematics and muscle activation. Specifically the runners adapted a more extended lumbar posture and reduced the lumbar paraspinal muscle activation after training. This effect carried over to shod running.

Published

2015