His primary areas of investigation include Artificial intelligence, Computer vision, Robot, Radiology and Simulation. His Artificial intelligence research is multidisciplinary, relying on both Laparoscopic surgery and Early results. His Computer vision research includes elements of Cadaver and Medical imaging.
His Robot study integrates concerns from other disciplines, such as Ultrasound probe and Haptic technology. His work on Computed tomography as part of his general Radiology study is frequently connected to Data processing, thereby bridging the divide between different branches of science. His Simulation research incorporates elements of Robotics, Pneumatic actuator and Artificial muscle.
Artificial intelligence, Computer vision, Robot, Biomedical engineering and Surgery are his primary areas of study. His work deals with themes such as Laparoscopic surgery, Radiology and Position, which intersect with Artificial intelligence. His study in the field of Iliac artery also crosses realms of Iliac Aneurysm.
His study in Computer vision concentrates on Tracking, Visual servoing and Image registration. His Robot research is multidisciplinary, incorporating perspectives in Control system, Simulation, Haptic technology and Human–computer interaction. Philippe Cinquin frequently studies issues relating to Endoscope and Simulation.
Philippe Cinquin mostly deals with Biomedical engineering, Nanotechnology, Biofuel Cells, Carbon nanotube and Laparoscopic surgery. His study in Biomedical engineering is interdisciplinary in nature, drawing from both Cadaveric spasm and Cartilage. The concepts of his Carbon nanotube study are interwoven with issues in Chitosan, Acetic acid, Electrochemistry and Buffer solution.
His research in Laparoscopic surgery intersects with topics in Endoscope, Machine vision, Computer vision and Robotic surgery. He works mostly in the field of Computer vision, limiting it down to concerns involving Strain gauge and, occasionally, Artificial intelligence. His Enzymatic biofuel cell research incorporates themes from Glucose oxidase and Biochemistry.
Philippe Cinquin mainly investigates Biomedical engineering, Biofuel Cells, Laparoscopic surgery, Carbon nanotube and Chitosan. His Biomedical engineering research includes themes of Beam, Timoshenko beam theory, Soft tissue, Base and Trajectory. His work in the fields of Biofuel Cells, such as Enzymatic biofuel cell, intersects with other areas such as Power output, Biofuel and Living body.
His work carried out in the field of Laparoscopic surgery brings together such families of science as Endoscope and Robotic surgery, Machine vision, Computer vision, Artificial intelligence. His research on Artificial intelligence focuses in particular on Visual servoing. His Carbon nanotube study combines topics in areas such as Laccase, Genipin and Oxygen.
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Mediatorless high-power glucose biofuel cells based on compressed carbon nanotube-enzyme electrodes
Abdelkader Zebda;Chantal Gondran;Alan Le Goff;Michael Holzinger.
Nature Communications (2011)
A glucose biofuel cell implanted in rats.
Philippe Cinquin;Chantal Gondran;Fabien Giroud;Simon Mazabrard.
PLOS ONE (2010)
Single Glucose Biofuel Cells Implanted in Rats Power Electronic Devices
A. Zebda;S. Cosnier;J.-P. Alcaraz;M. Holzinger.
Scientific Reports (2013)
Method for determining the position of an organ
Cinquin Philippe;Lavallee Stephane;Dubois Francis;Brunie Lionel.
Process and device for the preoperative determination of the positioning data of endoprosthetic parts
Cinquin Philippe;Lavallee Stephane;Leitner Francois;Minfelde Richard.
[Computer-assisted knee arthroplasty: comparison with a conventional procedure. Results of 50 cases in a prospective randomized study].
D. Saragaglia;F. Picard;C. Chaussard;E. Montbarbon.
Revue De Chirurgie Orthopedique Et Reparatrice De L Appareil Moteur (2001)
Computer‐assisted spine surgery: A technique for accurate transpedicular screw fixation using CT data and a 3‐D optical localizer
S Lavallée;P Sautot;J Troccaz;P Cinquin.
Journal of Image Guided Surgery (1995)
A new robot architecture for tele-echography
A. Vilchis;J. Troccaz;P. Cinquin;K. Masuda.
international conference on robotics and automation (2003)
Image guided operating robot: a clinical application in stereotactic neurosurgery
S. Lavallee;J. Troccaz;L. Gaborit;P. Cinquin.
international conference on robotics and automation (1992)
Computer-Assisted Knee Anterior Cruciate Ligament Reconstruction: First Clinical Tests
Vincent Dessenne;Stéphane Lavallée;Rémi Julliard;Rachel Orti.
Journal of Image Guided Surgery (1995)
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