Callum Faris scite author profile

IMPORTANCE The severity of a health state may be quantified using health utility measures. The utility of flaccid unilateral facial paralysis and unilateral moderate to severe postparalytic facial nerve syndrome with synkinesis may be challenging to discern from photographs alone. OBJECTIVE To determine the societal health utility of flaccid unilateral facial paralysis, unilateral moderate to severe postparalytic facial nerve syndrome, and post-facial reanimation using standard video. DESIGN, SETTING, AND PARTICIPANTS This survey study was conducted at the Massachusetts Eye and Ear and the Harvard Decision Science Laboratory from June 14, 2017, to August 3, 2017. Healthy adult naïve observers were recruited through advertising in the Cambridge, Massachusetts, area. Participants (n = 298) completed the web-based, interactive survey in person. The survey comprised clinical vignettes consisting of symptom summaries, videos, and pictures depicting 5 health states. MAIN OUTCOMES AND MEASURES Adult naïve observers ranked the utility of 5 randomized health states (flaccid unilateral facial paralysis, unilateral moderate to severe postparalytic facial nerve syndrome, post-facial reanimation, monocular blindness, and binocular blindness) according to the visual analog scale (VAS), standard gamble (SG), and time trade-off (TTO) measures. Standard videos of patients' facial function were used. RESULTS In total, 377 naïve observers were recruited and completed the survey in its entirety. Of the 377 participants, 298 (79.0%) were included for analysis. Among the 298 participants, 151 (50.7%) were female, 146 (49.0%) were male, with a mean (SD) age of 33.0 (15.1) years. No differences in health utility scores (SD) were observed between flaccid unilateral facial paralysis and unilateral moderate to severe postparalytic facial nerve syndrome (

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Characterisation of the surface structure of 3D printed scaffolds for cell infiltration and surgical suturing

Ruiz‐Cantu

Gleadall

Faris

et al. 2016

Biofabrication

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A note on versions:The version presented here may differ from the published version or from the version of record. If you wish to cite this item you are advised to consult the publisher's version. Please see the repository url above for details on accessing the published version and note that access may require a subscription.For more information, please contact eprints@nottingham.ac.uk Abstract3D printing is of great interest for tissue engineering scaffolds due to the ability to form complex geometries and control internal structures, including porosity and pore size. The porous structure of scaffolds plays an important role in cell ingrowth and nutrition infusion. Although the internal porosity and pore size of 3D printed scaffolds have been frequently studied, the surface porosity and pore size, which are critical for cell infiltration and mass transport, have not been investigated. The surface geometry can differ considerably from the internal scaffold structure depending on the 3D printing process. It is vital to be able to control the surface geometry of scaffolds as well as the internal structure to fabricate optimal architectures. This work presents a method to control the surface porosity and pore size of 3D printed scaffolds. Six scaffold designs have been printed with surface porosities ranging from 3% -21%. We have characterised the overall scaffold porosity and surface porosity using optical microscopy and microCT. It has been found that surface porosity has a significant impact on cell infiltration and proliferation. In addition, the porosity of the surface has been found to have an effect on mechanical properties and on the forces required to penetrate the scaffold with a surgical suturing needle. To the authors' knowledge, this study is the first to investigate the surface geometry of extrusion-based 3D printed scaffolds and demonstrates the importance of surface geometry in cell infiltration and clinical manipulation.

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Callum Faris

Multi-material 3D bioprinting of porous constructs for cartilage regeneration

Evaluation of Societal Health Utility of Facial Palsy and Facial Reanimation

Characterisation of the surface structure of 3D printed scaffolds for cell infiltration and surgical suturing

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