Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.

Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.

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Superior document:Springer Theses Series
:
Fichera, Loris.
Place / Publishing House:Cham : : Springer International Publishing AG,, 2016.
Ã2016.
Year of Publication:2016
Edition:1st ed.
Language:English
Series:Springer Theses Series
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Physical Description:1 online resource (114 pages)
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id 5006422851
ctrlnum (MiAaPQ)5006422851
(Au-PeEL)EBL6422851
(OCoLC)1076233831
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spelling Fichera, Loris.
Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
1st ed.
Cham : Springer International Publishing AG, 2016.
Ã2016.
1 online resource (114 pages)
text txt rdacontent
computer c rdamedia
online resource cr rdacarrier
Springer Theses Series
Intro -- Parts of this thesis have been published in the following documents: -- Journal Publications -- Conference Proceedings -- Workshop Abstracts -- Supervisors' Foreword -- Acknowledgments -- Contents -- About the Author -- 1 Introduction -- 1.1 Motivations -- 1.2 Components of the Research -- 1.3 Scope of the Thesis -- 1.4 Outline of the Thesis -- References -- 2 Background: Laser Technology and Applications to Clinical Surgery -- 2.1 Physical Properties of Light -- 2.2 Fundamentals of Lasers -- 2.2.1 Laser Beam Optics -- 2.2.2 Spectral Properties of Laser Light -- 2.3 Fundamentals of Laser-Matter Interaction -- 2.4 Interactions of Lasers with Biological Tissues -- 2.4.1 Thermal Interactions -- 2.4.2 Applications to Clinical Surgery -- References -- 3 Cognitive Supervision for Transoral Laser Microsurgery -- 3.1 Workflow of Transoral Laser Microsurgery -- 3.2 Technical Limitations of Transoral Laser Microsurgery -- 3.3 Supervision of the Laser Incision Process -- 3.3.1 Monitoring of Tissue Overheating -- 3.3.2 Monitoring of the Laser Incision Depth -- 3.4 Cognitive Models -- 3.5 Problem Formulation -- 3.5.1 Temperature Hypothesis -- 3.5.2 Laser Incision Depth Hypothesis -- 3.6 Materials and Methods -- 3.6.1 Controlled Incision of Soft Tissue -- 3.6.2 Tissue Targets -- 3.6.3 Measurement of Temperature During Laser Irradiation -- 3.6.4 Measurement of Depth of Incision -- References -- 4 Learning the Temperature Dynamics During Thermal Laser Ablation -- 4.1 Preliminary Considerations -- 4.2 Single-Point Ablation -- 4.2.1 Fitting a Gaussian Function -- 4.2.2 Meta-Parameters Dynamics -- 4.2.3 Experiments -- 4.2.4 Results -- 4.2.5 Discussion -- 4.3 Temperature Dynamics During Laser Scanning -- 4.3.1 Experiments -- 4.3.2 Results -- 4.3.3 Model Validation -- 4.3.4 Discussion -- References -- 5 Modeling the Laser Ablation Process.
5.1 Preliminary Considerations -- 5.2 Influencing Parameters -- 5.2.1 Influence of Energy Delivery Mode -- 5.2.2 Influence of Scanning Frequency -- 5.3 Incision Depth in Ex-Vivo Soft Tissue -- 5.4 Inverse Model of Depth -- 5.5 Ablation by Incision Superposition -- 5.5.1 Ablation Model -- 5.5.2 Controlled Ablation -- 5.5.3 Ablation Assessment -- 5.5.4 Results -- 5.6 Discussion -- References -- 6 Realization of a Cognitive Supervisory System for Laser Microsurgery -- 6.1 Introduction: The RALP Surgical System -- 6.1.1 Hardware Components -- 6.1.2 Software Architecture -- 6.2 System Implementation -- 6.2.1 Software Architecture -- 6.2.2 Integration with the Surgical Console -- 6.3 Towards Assistive Technologies for Laser Microsurgery -- References -- 7 Conclusions and Future Research Directions -- 7.1 Concluding Remarks -- 7.2 Future Research Directions -- 7.2.1 Clinical Translation -- 7.2.2 Online Learning -- 7.2.3 Automatic Control of Tissue Thermal Damage -- 7.2.4 Training of Laser Surgeons -- References -- Appendix ARequirements Questionnaire -- Appendix BSolution to the Homogeneous HeatConduction Equation -- Appendix CGaussian Ablation Shape.
Description based on publisher supplied metadata and other sources.
Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.
Electronic books.
Print version: Fichera, Loris Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery Cham : Springer International Publishing AG,c2016 9783319303291
ProQuest (Firm)
https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6422851 Click to View
language English
format eBook
author Fichera, Loris.
spellingShingle Fichera, Loris.
Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
Springer Theses Series
Intro -- Parts of this thesis have been published in the following documents: -- Journal Publications -- Conference Proceedings -- Workshop Abstracts -- Supervisors' Foreword -- Acknowledgments -- Contents -- About the Author -- 1 Introduction -- 1.1 Motivations -- 1.2 Components of the Research -- 1.3 Scope of the Thesis -- 1.4 Outline of the Thesis -- References -- 2 Background: Laser Technology and Applications to Clinical Surgery -- 2.1 Physical Properties of Light -- 2.2 Fundamentals of Lasers -- 2.2.1 Laser Beam Optics -- 2.2.2 Spectral Properties of Laser Light -- 2.3 Fundamentals of Laser-Matter Interaction -- 2.4 Interactions of Lasers with Biological Tissues -- 2.4.1 Thermal Interactions -- 2.4.2 Applications to Clinical Surgery -- References -- 3 Cognitive Supervision for Transoral Laser Microsurgery -- 3.1 Workflow of Transoral Laser Microsurgery -- 3.2 Technical Limitations of Transoral Laser Microsurgery -- 3.3 Supervision of the Laser Incision Process -- 3.3.1 Monitoring of Tissue Overheating -- 3.3.2 Monitoring of the Laser Incision Depth -- 3.4 Cognitive Models -- 3.5 Problem Formulation -- 3.5.1 Temperature Hypothesis -- 3.5.2 Laser Incision Depth Hypothesis -- 3.6 Materials and Methods -- 3.6.1 Controlled Incision of Soft Tissue -- 3.6.2 Tissue Targets -- 3.6.3 Measurement of Temperature During Laser Irradiation -- 3.6.4 Measurement of Depth of Incision -- References -- 4 Learning the Temperature Dynamics During Thermal Laser Ablation -- 4.1 Preliminary Considerations -- 4.2 Single-Point Ablation -- 4.2.1 Fitting a Gaussian Function -- 4.2.2 Meta-Parameters Dynamics -- 4.2.3 Experiments -- 4.2.4 Results -- 4.2.5 Discussion -- 4.3 Temperature Dynamics During Laser Scanning -- 4.3.1 Experiments -- 4.3.2 Results -- 4.3.3 Model Validation -- 4.3.4 Discussion -- References -- 5 Modeling the Laser Ablation Process.
5.1 Preliminary Considerations -- 5.2 Influencing Parameters -- 5.2.1 Influence of Energy Delivery Mode -- 5.2.2 Influence of Scanning Frequency -- 5.3 Incision Depth in Ex-Vivo Soft Tissue -- 5.4 Inverse Model of Depth -- 5.5 Ablation by Incision Superposition -- 5.5.1 Ablation Model -- 5.5.2 Controlled Ablation -- 5.5.3 Ablation Assessment -- 5.5.4 Results -- 5.6 Discussion -- References -- 6 Realization of a Cognitive Supervisory System for Laser Microsurgery -- 6.1 Introduction: The RALP Surgical System -- 6.1.1 Hardware Components -- 6.1.2 Software Architecture -- 6.2 System Implementation -- 6.2.1 Software Architecture -- 6.2.2 Integration with the Surgical Console -- 6.3 Towards Assistive Technologies for Laser Microsurgery -- References -- 7 Conclusions and Future Research Directions -- 7.1 Concluding Remarks -- 7.2 Future Research Directions -- 7.2.1 Clinical Translation -- 7.2.2 Online Learning -- 7.2.3 Automatic Control of Tissue Thermal Damage -- 7.2.4 Training of Laser Surgeons -- References -- Appendix ARequirements Questionnaire -- Appendix BSolution to the Homogeneous HeatConduction Equation -- Appendix CGaussian Ablation Shape.
author_facet Fichera, Loris.
author_variant l f lf
author_sort Fichera, Loris.
title Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
title_full Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
title_fullStr Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
title_full_unstemmed Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
title_auth Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
title_new Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
title_sort cognitive supervision for robot-assisted minimally invasive laser surgery.
series Springer Theses Series
series2 Springer Theses Series
publisher Springer International Publishing AG,
publishDate 2016
physical 1 online resource (114 pages)
edition 1st ed.
contents Intro -- Parts of this thesis have been published in the following documents: -- Journal Publications -- Conference Proceedings -- Workshop Abstracts -- Supervisors' Foreword -- Acknowledgments -- Contents -- About the Author -- 1 Introduction -- 1.1 Motivations -- 1.2 Components of the Research -- 1.3 Scope of the Thesis -- 1.4 Outline of the Thesis -- References -- 2 Background: Laser Technology and Applications to Clinical Surgery -- 2.1 Physical Properties of Light -- 2.2 Fundamentals of Lasers -- 2.2.1 Laser Beam Optics -- 2.2.2 Spectral Properties of Laser Light -- 2.3 Fundamentals of Laser-Matter Interaction -- 2.4 Interactions of Lasers with Biological Tissues -- 2.4.1 Thermal Interactions -- 2.4.2 Applications to Clinical Surgery -- References -- 3 Cognitive Supervision for Transoral Laser Microsurgery -- 3.1 Workflow of Transoral Laser Microsurgery -- 3.2 Technical Limitations of Transoral Laser Microsurgery -- 3.3 Supervision of the Laser Incision Process -- 3.3.1 Monitoring of Tissue Overheating -- 3.3.2 Monitoring of the Laser Incision Depth -- 3.4 Cognitive Models -- 3.5 Problem Formulation -- 3.5.1 Temperature Hypothesis -- 3.5.2 Laser Incision Depth Hypothesis -- 3.6 Materials and Methods -- 3.6.1 Controlled Incision of Soft Tissue -- 3.6.2 Tissue Targets -- 3.6.3 Measurement of Temperature During Laser Irradiation -- 3.6.4 Measurement of Depth of Incision -- References -- 4 Learning the Temperature Dynamics During Thermal Laser Ablation -- 4.1 Preliminary Considerations -- 4.2 Single-Point Ablation -- 4.2.1 Fitting a Gaussian Function -- 4.2.2 Meta-Parameters Dynamics -- 4.2.3 Experiments -- 4.2.4 Results -- 4.2.5 Discussion -- 4.3 Temperature Dynamics During Laser Scanning -- 4.3.1 Experiments -- 4.3.2 Results -- 4.3.3 Model Validation -- 4.3.4 Discussion -- References -- 5 Modeling the Laser Ablation Process.
5.1 Preliminary Considerations -- 5.2 Influencing Parameters -- 5.2.1 Influence of Energy Delivery Mode -- 5.2.2 Influence of Scanning Frequency -- 5.3 Incision Depth in Ex-Vivo Soft Tissue -- 5.4 Inverse Model of Depth -- 5.5 Ablation by Incision Superposition -- 5.5.1 Ablation Model -- 5.5.2 Controlled Ablation -- 5.5.3 Ablation Assessment -- 5.5.4 Results -- 5.6 Discussion -- References -- 6 Realization of a Cognitive Supervisory System for Laser Microsurgery -- 6.1 Introduction: The RALP Surgical System -- 6.1.1 Hardware Components -- 6.1.2 Software Architecture -- 6.2 System Implementation -- 6.2.1 Software Architecture -- 6.2.2 Integration with the Surgical Console -- 6.3 Towards Assistive Technologies for Laser Microsurgery -- References -- 7 Conclusions and Future Research Directions -- 7.1 Concluding Remarks -- 7.2 Future Research Directions -- 7.2.1 Clinical Translation -- 7.2.2 Online Learning -- 7.2.3 Automatic Control of Tissue Thermal Damage -- 7.2.4 Training of Laser Surgeons -- References -- Appendix ARequirements Questionnaire -- Appendix BSolution to the Homogeneous HeatConduction Equation -- Appendix CGaussian Ablation Shape.
isbn 9783319303307
9783319303291
callnumber-first R - Medicine
callnumber-subject R - General Medicine
callnumber-label R856-857
callnumber-sort R 3856 3857
genre Electronic books.
genre_facet Electronic books.
url https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6422851
illustrated Not Illustrated
dewey-hundreds 600 - Technology
dewey-tens 610 - Medicine & health
dewey-ones 617 - Surgery & related medical specialties
dewey-full 617.058
dewey-sort 3617.058
dewey-raw 617.058
dewey-search 617.058
oclc_num 1076233831
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is_hierarchy_title Cognitive Supervision for Robot-Assisted Minimally Invasive Laser Surgery.
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marc_error Info : Unimarc and ISO-8859-1 translations identical, choosing ISO-8859-1. --- [ 856 : z ]
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