Current and future applications of virtual reality for medicine
Identifieur interne : 001600 ( PascalFrancis/Corpus ); précédent : 001599; suivant : 001601Current and future applications of virtual reality for medicine
Auteurs : R. M. Satava ; S. B. JonesSource :
- Proceedings of the IEEE [ 0018-9219 ] ; 1998.
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- Pascal (Inist)
English descriptors
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Abstract
Virtual reality is just emerging as an accepted scientific discipline for medicine. The majority of near-term applications are in the area of surgical planning, interoperative navigation, and surgical simulations. Its use in rehabilitative medicine and psychiatry has made significant progress. The immediate future holds promise for virtual endoscopy, which may replace standard endoscopic procedures for diagnostic screening. Viewing of these virtual images may be with head-mounted displays or true suspended holograms. The most highly developed area is in surgical simulations. Current generations are approaching photorealistic representation of the anatomy, while measurement science is providing physical tissue properties and physiologic parameters. The types of simulations range from "needle-based" procedures, such as standard intravenous insertion, central venous placement catheter, and chest-tube insertion to more sophisticated simulations of full surgical procedures like laparoscopic cholecystectomy or hysteroscopic resection of interuterine myoma. In addition, haptic input devices are providing the sense of touch to the procedures. Soon there will be patient-specific models derived from computed tomography or magnetic resonance imaging scans that will permit a surgeon to practice a delicate surgical procedure on the patient's specific virtual anatomy before actually performing the procedure on the patient. These applications will afford the surgeon the opportunity to provide the highest surgical care possible through the use of advanced technologies.
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Pour connaître la documentation sur le format Inist Standard.
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Format Inist (serveur)
NO : | PASCAL 98-0330746 INIST |
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ET : | Current and future applications of virtual reality for medicine |
AU : | SATAVA (R. M.); JONES (S. B.); MERRIL (Gregory) |
AF : | Department of Surgery, Yale University School of Medicine/New Haven, CT 06510/Etats-Unis (1 aut.); Advanced Biomedical Technology Program, Defense Advanced Research Projects Agency/Arlington, VA 22225/Etats-Unis (1 aut.); Uniformed Services University of the Health Sciences/Bethesda, MD 20814/Etats-Unis (2 aut.); Advanced Biotechnology Program, Defense Advanced Research Projects Agency/Arlington, VA 22225/Etats-Unis (2 aut.); HT Medical Systems, Inc./Rockville, MD 20852-4874/Etats-Unis (1 aut.) |
DT : | Publication en série; Niveau analytique |
SO : | Proceedings of the IEEE; ISSN 0018-9219; Coden IEEPAD; Etats-Unis; Da. 1998; Vol. 86; No. 3; Pp. 484-489; Bibl. 9 ref. |
LA : | Anglais |
EA : | Virtual reality is just emerging as an accepted scientific discipline for medicine. The majority of near-term applications are in the area of surgical planning, interoperative navigation, and surgical simulations. Its use in rehabilitative medicine and psychiatry has made significant progress. The immediate future holds promise for virtual endoscopy, which may replace standard endoscopic procedures for diagnostic screening. Viewing of these virtual images may be with head-mounted displays or true suspended holograms. The most highly developed area is in surgical simulations. Current generations are approaching photorealistic representation of the anatomy, while measurement science is providing physical tissue properties and physiologic parameters. The types of simulations range from "needle-based" procedures, such as standard intravenous insertion, central venous placement catheter, and chest-tube insertion to more sophisticated simulations of full surgical procedures like laparoscopic cholecystectomy or hysteroscopic resection of interuterine myoma. In addition, haptic input devices are providing the sense of touch to the procedures. Soon there will be patient-specific models derived from computed tomography or magnetic resonance imaging scans that will permit a surgeon to practice a delicate surgical procedure on the patient's specific virtual anatomy before actually performing the procedure on the patient. These applications will afford the surgeon the opportunity to provide the highest surgical care possible through the use of advanced technologies. |
CC : | 002B28D |
FD : | Réalité virtuelle; Application médicale; Chirurgie; Enseignement; Simulation; Homme; Représentation tridimensionnelle |
ED : | Virtual reality; Medical application; Surgery; Teaching; Simulation; Human; Three dimensional representation |
GD : | Medizinische Technik; Ausbildung; Simulation |
SD : | Realidad virtual; Aplicación medical; Cirugía; Enseñanza; Simulación; Hombre; Representación tridimensional |
LO : | INIST-222.354000079234940030 |
ID : | 98-0330746 |
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Pascal:98-0330746Le document en format XML
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<front><div type="abstract" xml:lang="en">Virtual reality is just emerging as an accepted scientific discipline for medicine. The majority of near-term applications are in the area of surgical planning, interoperative navigation, and surgical simulations. Its use in rehabilitative medicine and psychiatry has made significant progress. The immediate future holds promise for virtual endoscopy, which may replace standard endoscopic procedures for diagnostic screening. Viewing of these virtual images may be with head-mounted displays or true suspended holograms. The most highly developed area is in surgical simulations. Current generations are approaching photorealistic representation of the anatomy, while measurement science is providing physical tissue properties and physiologic parameters. The types of simulations range from "needle-based" procedures, such as standard intravenous insertion, central venous placement catheter, and chest-tube insertion to more sophisticated simulations of full surgical procedures like laparoscopic cholecystectomy or hysteroscopic resection of interuterine myoma. In addition, haptic input devices are providing the sense of touch to the procedures. Soon there will be patient-specific models derived from computed tomography or magnetic resonance imaging scans that will permit a surgeon to practice a delicate surgical procedure on the patient's specific virtual anatomy before actually performing the procedure on the patient. These applications will afford the surgeon the opportunity to provide the highest surgical care possible through the use of advanced technologies.</div>
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<ET>Current and future applications of virtual reality for medicine</ET>
<AU>SATAVA (R. M.); JONES (S. B.); MERRIL (Gregory)</AU>
<AF>Department of Surgery, Yale University School of Medicine/New Haven, CT 06510/Etats-Unis (1 aut.); Advanced Biomedical Technology Program, Defense Advanced Research Projects Agency/Arlington, VA 22225/Etats-Unis (1 aut.); Uniformed Services University of the Health Sciences/Bethesda, MD 20814/Etats-Unis (2 aut.); Advanced Biotechnology Program, Defense Advanced Research Projects Agency/Arlington, VA 22225/Etats-Unis (2 aut.); HT Medical Systems, Inc./Rockville, MD 20852-4874/Etats-Unis (1 aut.)</AF>
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