Physics-based virtual environment for training core skills in vascular interventional radiological procedures

N. W. John; V. Luboz; F. Bello; C. Hughes; F. P. Vidal; I. S. Lim; T. V. How; J. Zhai; S. Johnson; N. Chalmers; K. Brodlie; A. Bulpit; Y. Song; D. O. Kessel; R. Phillips; J. W. Ward; S. Pisharody; Y. Zhang; C. M. Crawshaw; D. A. Gould

Physics-based virtual environment for training core skills in vascular interventional radiological procedures

N. W. John, V. Luboz, F. Bello, C. Hughes, F. P. Vidal, I. S. Lim, T. V. How, J. Zhai, S. Johnson, N. Chalmers, K. Brodlie, A. Bulpit, Y. Song, D. O. Kessel, R. Phillips, J. W. Ward, S. Pisharody, Y. Zhang, C. M. Crawshaw, D. A. Gould

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Recent years have seen a significant increase in the use of Interventional Radiology (IR) as an alternative to open surgery. A large number of IR procedures commences with needle puncture of a vessel to insert guidewires and catheters: these clinical skills are acquired by all radiologists during training on patients, associated with some discomfort and occasionally, complications. While some visual skills can be acquired using models such as the ones used in surgery, these have limitations for IR which relies heavily on a sense of touch. Both patients and trainees would benefit from a virtual environment (VE) conveying touch sensation to realistically mimic procedures. The authors are developing a high fidelity VE providing a validated alternative to the traditional apprenticeship model used for teaching the core skills. The current version of the CRaIVE simulator combines home made software, haptic devices and commercial equipments.

Original language	English
Title of host publication	Proceeding of Medicine Meets Virtual Reality 16 (MMVR16)
Place of Publication	Long Beach, California
Publisher	IOS Press
Pages	195-197
Number of pages	3
Volume	132
Publication status	Published - 1 Jan 2008
Event	Medicine Meets Virtual Reality 16 - Long Beach, United States Duration: 29 Jan 2008 → 1 Feb 2008 http://www.nextmed.com/

Publication series

Name	Studies in Health Technology and Informatics
Publisher	IOS Press

Conference

Conference	Medicine Meets Virtual Reality 16
Abbreviated title	MMVR16
Country/Territory	United States
City	Long Beach
Period	29/01/08 → 1/02/08
Internet address	http://www.nextmed.com/

Keywords

Virtual environment, patient specific model, interventional radiology

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John, N. W., Luboz, V., Bello, F., Hughes, C., Vidal, F. P., Lim, I. S., How, T. V., Zhai, J., Johnson, S., Chalmers, N., Brodlie, K., Bulpit, A., Song, Y., Kessel, D. O., Phillips, R., Ward, J. W., Pisharody, S., Zhang, Y., Crawshaw, C. M., & Gould, D. A. (2008). Physics-based virtual environment for training core skills in vascular interventional radiological procedures. In Proceeding of Medicine Meets Virtual Reality 16 (MMVR16) (Vol. 132, pp. 195-197). (Studies in Health Technology and Informatics). IOS Press.

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title = "Physics-based virtual environment for training core skills in vascular interventional radiological procedures",

abstract = "Recent years have seen a significant increase in the use of Interventional Radiology (IR) as an alternative to open surgery. A large number of IR procedures commences with needle puncture of a vessel to insert guidewires and catheters: these clinical skills are acquired by all radiologists during training on patients, associated with some discomfort and occasionally, complications. While some visual skills can be acquired using models such as the ones used in surgery, these have limitations for IR which relies heavily on a sense of touch. Both patients and trainees would benefit from a virtual environment (VE) conveying touch sensation to realistically mimic procedures. The authors are developing a high fidelity VE providing a validated alternative to the traditional apprenticeship model used for teaching the core skills. The current version of the CRaIVE simulator combines home made software, haptic devices and commercial equipments.",

keywords = "Virtual environment, patient specific model, interventional radiology",

author = "John, {N. W.} and V. Luboz and F. Bello and C. Hughes and Vidal, {F. P.} and Lim, {I. S.} and How, {T. V.} and J. Zhai and S. Johnson and N. Chalmers and K. Brodlie and A. Bulpit and Y. Song and Kessel, {D. O.} and R. Phillips and Ward, {J. W.} and S. Pisharody and Y. Zhang and Crawshaw, {C. M.} and Gould, {D. A.}",

year = "2008",

month = jan,

day = "1",

language = "English",

volume = "132",

series = "Studies in Health Technology and Informatics",

publisher = "IOS Press",

pages = "195--197",

booktitle = "Proceeding of Medicine Meets Virtual Reality 16 (MMVR16)",

note = "Medicine Meets Virtual Reality 16, MMVR16 ; Conference date: 29-01-2008 Through 01-02-2008",

url = "http://www.nextmed.com/",

}

John, NW, Luboz, V, Bello, F, Hughes, C, Vidal, FP, Lim, IS, How, TV, Zhai, J, Johnson, S, Chalmers, N, Brodlie, K, Bulpit, A, Song, Y, Kessel, DO, Phillips, R, Ward, JW, Pisharody, S, Zhang, Y, Crawshaw, CM & Gould, DA 2008, Physics-based virtual environment for training core skills in vascular interventional radiological procedures. in Proceeding of Medicine Meets Virtual Reality 16 (MMVR16). vol. 132, Studies in Health Technology and Informatics, IOS Press, Long Beach, California, pp. 195-197, Medicine Meets Virtual Reality 16, Long Beach, United States, 29/01/08.

Physics-based virtual environment for training core skills in vascular interventional radiological procedures. / John, N. W.; Luboz, V.; Bello, F. et al.
Proceeding of Medicine Meets Virtual Reality 16 (MMVR16). Vol. 132 Long Beach, California: IOS Press, 2008. p. 195-197 (Studies in Health Technology and Informatics).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Physics-based virtual environment for training core skills in vascular interventional radiological procedures

AU - John, N. W.

AU - Luboz, V.

AU - Bello, F.

AU - Hughes, C.

AU - Vidal, F. P.

AU - Lim, I. S.

AU - How, T. V.

AU - Zhai, J.

AU - Johnson, S.

AU - Chalmers, N.

AU - Brodlie, K.

AU - Bulpit, A.

AU - Song, Y.

AU - Kessel, D. O.

AU - Phillips, R.

AU - Ward, J. W.

AU - Pisharody, S.

AU - Zhang, Y.

AU - Crawshaw, C. M.

AU - Gould, D. A.

PY - 2008/1/1

Y1 - 2008/1/1

N2 - Recent years have seen a significant increase in the use of Interventional Radiology (IR) as an alternative to open surgery. A large number of IR procedures commences with needle puncture of a vessel to insert guidewires and catheters: these clinical skills are acquired by all radiologists during training on patients, associated with some discomfort and occasionally, complications. While some visual skills can be acquired using models such as the ones used in surgery, these have limitations for IR which relies heavily on a sense of touch. Both patients and trainees would benefit from a virtual environment (VE) conveying touch sensation to realistically mimic procedures. The authors are developing a high fidelity VE providing a validated alternative to the traditional apprenticeship model used for teaching the core skills. The current version of the CRaIVE simulator combines home made software, haptic devices and commercial equipments.

AB - Recent years have seen a significant increase in the use of Interventional Radiology (IR) as an alternative to open surgery. A large number of IR procedures commences with needle puncture of a vessel to insert guidewires and catheters: these clinical skills are acquired by all radiologists during training on patients, associated with some discomfort and occasionally, complications. While some visual skills can be acquired using models such as the ones used in surgery, these have limitations for IR which relies heavily on a sense of touch. Both patients and trainees would benefit from a virtual environment (VE) conveying touch sensation to realistically mimic procedures. The authors are developing a high fidelity VE providing a validated alternative to the traditional apprenticeship model used for teaching the core skills. The current version of the CRaIVE simulator combines home made software, haptic devices and commercial equipments.

KW - Virtual environment, patient specific model, interventional radiology

M3 - Conference contribution

VL - 132

T3 - Studies in Health Technology and Informatics

SP - 195

EP - 197

BT - Proceeding of Medicine Meets Virtual Reality 16 (MMVR16)

PB - IOS Press

CY - Long Beach, California

T2 - Medicine Meets Virtual Reality 16

Y2 - 29 January 2008 through 1 February 2008

ER -

Physics-based virtual environment for training core skills in vascular interventional radiological procedures

Abstract

Publication series

Conference

Keywords

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