Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis
High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to impr...
Ausführliche Beschreibung
Gespeichert in:
| Autor*in: |
Barbe, Kurt [verfasserIn] |
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| Format: |
Artikel |
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| Sprache: |
Englisch |
| Erschienen: |
2017 |
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| Schlagwörter: |
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| Übergeordnetes Werk: |
Enthalten in: IEEE transactions on instrumentation and measurement - New York, NY, 1963, 66(2017), 3, Seite 460-469 |
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| Übergeordnetes Werk: |
volume:66 ; year:2017 ; number:3 ; pages:460-469 |
| Links: |
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| DOI / URN: |
10.1109/TIM.2016.2610018 |
|---|
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OLC1990768385 |
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| 520 | |a High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. | ||
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| 650 | 4 | |a Linear approximation | |
| 650 | 4 | |a nonparametric | |
| 650 | 4 | |a Biological system modeling | |
| 650 | 4 | |a Surgery | |
| 650 | 4 | |a bipolar electrosurgery | |
| 650 | 4 | |a Mathematical model | |
| 650 | 4 | |a Bioimpedance spectra | |
| 650 | 4 | |a Kernel | |
| 650 | 4 | |a collagen denaturation | |
| 650 | 4 | |a Linear systems | |
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10.1109/TIM.2016.2610018 doi PQ20170301 (DE-627)OLC1990768385 (DE-599)GBVOLC1990768385 (PRQ)c945-a74f5516f47991c21d5293c3d0e412a33133cc1e9810153d9bb073ab383594680 (KEY)0079426020170000066000300460towardatissuemodelforbipolarelectrosurgeryblockori DE-627 ger DE-627 rakwb eng 620 DNB 50.21 bkl 53.00 bkl Barbe, Kurt verfasserin aut Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. Bioimpedance Linear approximation nonparametric Biological system modeling Surgery bipolar electrosurgery Mathematical model Bioimpedance spectra Kernel collagen denaturation Linear systems frequency response function (FRF) Ford, Carolyn oth Bonn, Kenlyn oth Gilbert, James oth Enthalten in IEEE transactions on instrumentation and measurement New York, NY, 1963 66(2017), 3, Seite 460-469 (DE-627)129358576 (DE-600)160442-9 (DE-576)014730863 0018-9456 nnns volume:66 year:2017 number:3 pages:460-469 http://dx.doi.org/10.1109/TIM.2016.2610018 Volltext http://ieeexplore.ieee.org/document/7828119 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC GBV_ILN_24 GBV_ILN_70 GBV_ILN_170 GBV_ILN_2014 GBV_ILN_2061 50.21 AVZ 53.00 AVZ AR 66 2017 3 460-469 |
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10.1109/TIM.2016.2610018 doi PQ20170301 (DE-627)OLC1990768385 (DE-599)GBVOLC1990768385 (PRQ)c945-a74f5516f47991c21d5293c3d0e412a33133cc1e9810153d9bb073ab383594680 (KEY)0079426020170000066000300460towardatissuemodelforbipolarelectrosurgeryblockori DE-627 ger DE-627 rakwb eng 620 DNB 50.21 bkl 53.00 bkl Barbe, Kurt verfasserin aut Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. Bioimpedance Linear approximation nonparametric Biological system modeling Surgery bipolar electrosurgery Mathematical model Bioimpedance spectra Kernel collagen denaturation Linear systems frequency response function (FRF) Ford, Carolyn oth Bonn, Kenlyn oth Gilbert, James oth Enthalten in IEEE transactions on instrumentation and measurement New York, NY, 1963 66(2017), 3, Seite 460-469 (DE-627)129358576 (DE-600)160442-9 (DE-576)014730863 0018-9456 nnns volume:66 year:2017 number:3 pages:460-469 http://dx.doi.org/10.1109/TIM.2016.2610018 Volltext http://ieeexplore.ieee.org/document/7828119 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC GBV_ILN_24 GBV_ILN_70 GBV_ILN_170 GBV_ILN_2014 GBV_ILN_2061 50.21 AVZ 53.00 AVZ AR 66 2017 3 460-469 |
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10.1109/TIM.2016.2610018 doi PQ20170301 (DE-627)OLC1990768385 (DE-599)GBVOLC1990768385 (PRQ)c945-a74f5516f47991c21d5293c3d0e412a33133cc1e9810153d9bb073ab383594680 (KEY)0079426020170000066000300460towardatissuemodelforbipolarelectrosurgeryblockori DE-627 ger DE-627 rakwb eng 620 DNB 50.21 bkl 53.00 bkl Barbe, Kurt verfasserin aut Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. Bioimpedance Linear approximation nonparametric Biological system modeling Surgery bipolar electrosurgery Mathematical model Bioimpedance spectra Kernel collagen denaturation Linear systems frequency response function (FRF) Ford, Carolyn oth Bonn, Kenlyn oth Gilbert, James oth Enthalten in IEEE transactions on instrumentation and measurement New York, NY, 1963 66(2017), 3, Seite 460-469 (DE-627)129358576 (DE-600)160442-9 (DE-576)014730863 0018-9456 nnns volume:66 year:2017 number:3 pages:460-469 http://dx.doi.org/10.1109/TIM.2016.2610018 Volltext http://ieeexplore.ieee.org/document/7828119 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC GBV_ILN_24 GBV_ILN_70 GBV_ILN_170 GBV_ILN_2014 GBV_ILN_2061 50.21 AVZ 53.00 AVZ AR 66 2017 3 460-469 |
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10.1109/TIM.2016.2610018 doi PQ20170301 (DE-627)OLC1990768385 (DE-599)GBVOLC1990768385 (PRQ)c945-a74f5516f47991c21d5293c3d0e412a33133cc1e9810153d9bb073ab383594680 (KEY)0079426020170000066000300460towardatissuemodelforbipolarelectrosurgeryblockori DE-627 ger DE-627 rakwb eng 620 DNB 50.21 bkl 53.00 bkl Barbe, Kurt verfasserin aut Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. Bioimpedance Linear approximation nonparametric Biological system modeling Surgery bipolar electrosurgery Mathematical model Bioimpedance spectra Kernel collagen denaturation Linear systems frequency response function (FRF) Ford, Carolyn oth Bonn, Kenlyn oth Gilbert, James oth Enthalten in IEEE transactions on instrumentation and measurement New York, NY, 1963 66(2017), 3, Seite 460-469 (DE-627)129358576 (DE-600)160442-9 (DE-576)014730863 0018-9456 nnns volume:66 year:2017 number:3 pages:460-469 http://dx.doi.org/10.1109/TIM.2016.2610018 Volltext http://ieeexplore.ieee.org/document/7828119 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC GBV_ILN_24 GBV_ILN_70 GBV_ILN_170 GBV_ILN_2014 GBV_ILN_2061 50.21 AVZ 53.00 AVZ AR 66 2017 3 460-469 |
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10.1109/TIM.2016.2610018 doi PQ20170301 (DE-627)OLC1990768385 (DE-599)GBVOLC1990768385 (PRQ)c945-a74f5516f47991c21d5293c3d0e412a33133cc1e9810153d9bb073ab383594680 (KEY)0079426020170000066000300460towardatissuemodelforbipolarelectrosurgeryblockori DE-627 ger DE-627 rakwb eng 620 DNB 50.21 bkl 53.00 bkl Barbe, Kurt verfasserin aut Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis 2017 Text txt rdacontent ohne Hilfsmittel zu benutzen n rdamedia Band nc rdacarrier High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. Bioimpedance Linear approximation nonparametric Biological system modeling Surgery bipolar electrosurgery Mathematical model Bioimpedance spectra Kernel collagen denaturation Linear systems frequency response function (FRF) Ford, Carolyn oth Bonn, Kenlyn oth Gilbert, James oth Enthalten in IEEE transactions on instrumentation and measurement New York, NY, 1963 66(2017), 3, Seite 460-469 (DE-627)129358576 (DE-600)160442-9 (DE-576)014730863 0018-9456 nnns volume:66 year:2017 number:3 pages:460-469 http://dx.doi.org/10.1109/TIM.2016.2610018 Volltext http://ieeexplore.ieee.org/document/7828119 GBV_USEFLAG_A SYSFLAG_A GBV_OLC SSG-OLC-TEC GBV_ILN_24 GBV_ILN_70 GBV_ILN_170 GBV_ILN_2014 GBV_ILN_2061 50.21 AVZ 53.00 AVZ AR 66 2017 3 460-469 |
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| author |
Barbe, Kurt |
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Barbe, Kurt ddc 620 bkl 50.21 bkl 53.00 misc Bioimpedance misc Linear approximation misc nonparametric misc Biological system modeling misc Surgery misc bipolar electrosurgery misc Mathematical model misc Bioimpedance spectra misc Kernel misc collagen denaturation misc Linear systems misc frequency response function (FRF) Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis |
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620 DNB 50.21 bkl 53.00 bkl Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis Bioimpedance Linear approximation nonparametric Biological system modeling Surgery bipolar electrosurgery Mathematical model Bioimpedance spectra Kernel collagen denaturation Linear systems frequency response function (FRF) |
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ddc 620 bkl 50.21 bkl 53.00 misc Bioimpedance misc Linear approximation misc nonparametric misc Biological system modeling misc Surgery misc bipolar electrosurgery misc Mathematical model misc Bioimpedance spectra misc Kernel misc collagen denaturation misc Linear systems misc frequency response function (FRF) |
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ddc 620 bkl 50.21 bkl 53.00 misc Bioimpedance misc Linear approximation misc nonparametric misc Biological system modeling misc Surgery misc bipolar electrosurgery misc Mathematical model misc Bioimpedance spectra misc Kernel misc collagen denaturation misc Linear systems misc frequency response function (FRF) |
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ddc 620 bkl 50.21 bkl 53.00 misc Bioimpedance misc Linear approximation misc nonparametric misc Biological system modeling misc Surgery misc bipolar electrosurgery misc Mathematical model misc Bioimpedance spectra misc Kernel misc collagen denaturation misc Linear systems misc frequency response function (FRF) |
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Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis |
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Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis |
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toward a tissue model for bipolar electrosurgery: block-oriented model structure analysis |
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Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis |
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High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. |
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High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. |
| abstract_unstemmed |
High-frequency radio energy is applied to tissue therapeutically in a number of different medical applications. The ability to model the effects of RF energy on the collagen, elastin, and liquid content of the target tissue would allow for the refinement of the control of the energy in order to improve outcomes and reduce negative side effects. In this paper, we aim at studying the dynamics of voltage and current signals in bipolar electrosurgery whose dynamic relationship we describe by a nonlinear (NL) time-varying dynamical model. The different aspects and carefully designed tests allow getting insight in a possible candidate for such a dynamical model. We conclude, in this paper, that the impedance relationship may be modeled through a time-varying Wiener-Hammerstein system where the static NL function is a function of both the signal as well as time. In particular, we motivate that one can discriminate between different target tissues through this model by inspecting the time-varying NL function. As such, the model properties serve the realization of a possible simulator generating real-life current-voltage signals for training facilities among other applications. |
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Toward a Tissue Model for Bipolar Electrosurgery: Block-Oriented Model Structure Analysis |
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Ford, Carolyn Bonn, Kenlyn Gilbert, James |
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