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Eye (London, England)
Jan, 2014;28 (1): 78-84.

Development of a virtual reality training curriculum for phacoemulsification surgery.

A V Spiteri, R Aggarwal, T L Kersey, M Sira, L Benjamin, A W Darzi, P A Bloom
Author Information
  1. A V Spiteri: London Kent Surrey Sussex Deanery, London, UK.
  2. R Aggarwal: Division of Surgery, Department of Surgery and Cancer, Imperial College London, London, UK.
  3. T L Kersey: Hillingdon Hospital, Western Eye Hospital, London, UK.
  4. M Sira: Queen Alexandra Hospital, Portsmouth, UK.
  5. L Benjamin: 1] Stoke Mandeville Hospital, Buckinghamshire, UK [2] Education Committee of the Royal College of Ophthalmologists, London, UK.
  6. A W Darzi: Imperial College, Imperial College Hospital NHS Trust, Royal Marsden Hospital, Institute of Cancer Research, London, UK.
  7. P A Bloom: The Hillingdon Hospital NHS Foundation Trust and The Western Eye Hospital (Imperial College NHS Trust), Imperial College School of Medicine, Middlesex University, London, UK.
PMID: 24071776 DOI: 10.1038/eye.2013.211

Abstract

PURPOSE: Training within a proficiency-based virtual reality (VR) curriculum may reduce errors during real surgical procedures. This study used a scientific methodology to develop a VR training curriculum for phacoemulsification surgery (PS).
PATIENTS AND METHODS: Ten novice-(n) (performed <10 cataract operations), 10 intermediate-(i) (50-200), and 10 experienced-(e) (>500) surgeons were recruited. Construct validity was defined as the ability to differentiate between the three levels of experience, based on the simulator-derived metrics for two abstract modules (four tasks) and three procedural modules (five tasks) on a high-fidelity VR simulator. Proficiency measures were based on the performance of experienced surgeons.
RESULTS: Abstract modules demonstrated a 'ceiling effect' with construct validity established between groups (n) and (i) but not between groups (i) and (e)-Forceps 1 (46, 87, and 95; P<0.001). Increasing difficulty of task showed significantly reduced performance in (n) but minimal difference for (i) and (e)-Anti-tremor 4 (0, 51, and 59; P<0.001), Forceps 4 (11, 73, and 94; P<0.001). Procedural modules were found to be construct valid between groups (n) and (i) and between groups (i) and (e)-Lens-cracking (0, 22, and 51; P<0.05) and Phaco-quadrants (16, 53, and 87; P<0.05). This was also the case with Capsulorhexis (0, 19, and 63; P<0.05) with the performance decreasing in the (n) and (i) group but improving in the (e) group (0, 55, and 73; P<0.05) and (0, 48, and 76; P<0.05) as task difficulty increased.
CONCLUSION: Experienced/intermediate benchmark skill levels are defined allowing the development of a proficiency-based VR training curriculum for PS for novices using a structured scientific methodology.

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MeSH Term

Clinical Competence
Computer Simulation
Curriculum
Education, Medical, Graduate
Educational Measurement
Humans
Learning Curve
Phacoemulsification
Surgery, Computer-Assisted
Teaching
User-Computer Interface
Journal Article Research Support, Non-U.S. Gov't

Word Cloud

Created with Highcharts 10.0.0P<0ne005VRcurriculummodulesgroupstrainingperformance001proficiency-basedvirtualrealityscientificmethodologyphacoemulsificationsurgeryPS10surgeonsvaliditydefinedthreelevelsbasedtasksconstruct87difficultytask45173groupPURPOSE:TrainingwithinmayreduceerrorsrealsurgicalproceduresstudyuseddevelopPATIENTSANDMETHODS:Tennovice-performed<10cataractoperationsintermediate-50-200experienced->500recruitedConstructabilitydifferentiateexperiencesimulator-derivedmetricstwoabstractfourproceduralfivehigh-fidelitysimulatorProficiencymeasuresexperiencedRESULTS:Abstractdemonstrated'ceilingeffect'established-Forceps14695Increasingshowedsignificantlyreducedminimaldifference-Anti-tremor59Forceps1194Proceduralfoundvalid-Lens-cracking22Phaco-quadrants1653alsocaseCapsulorhexis1963decreasingimproving554876increasedCONCLUSION:Experienced/intermediatebenchmarkskillallowingdevelopmentnovicesusingstructuredDevelopment

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