DR. RAYMOND YUEN-FONG CHAN, M.D.
Medical Practice at Convoy St, San Diego, CA

2013021, Aug 15, 2013

Mar 29, 2011

13/695678

Jinnan Wang - Seattle WA, US
Raymond Chan - San Diego CA, US
Gert Wim 'T Hooft - Eindhoven, NL
Adrien Emmanuel Desjardin - Waterloo, CA
Christopher Stephen Hall - Hopewell Junction NY, US

KONINKLIJKE PHILIPS ELECTRONICS N.V. - EINDHOVEN

A61B 6/00, A61B 5/11, A61B 8/12, A61B 6/03, A61B 5/055, A61B 5/00, A61B 5/113

600476

An optical motion sensing system () for use in imaging an anatomical structure employs an optical motion sensor () including a body contour conforming matrix (“BCCM”) () and an optical fiber (). Upon BCCM () being adjoined to the anatomical structure, BCCM () structurally conforms at least partially to a surface contour of the anatomical structure for reciprocating any motion by the anatomical structure. Optical fiber () is at least partially embedded in the BCCM () for generating an encoded optical signal () indicative of a shape of the optical fiber () responsive to any SOS reciprocal motion by the BCCM () during an imaging of the anatomical structure. System () further employs a motion tracker () responsive to encoded optical signal () for periodically reconstructing the shape of optical fiber () with each change in the shape of optical fiber () representing motion by the anatomical structure.

2013029, Nov 7, 2013

Jan 25, 2012

13/979283

Aleksandra Popovic - New York NY, US
Emil George Radulescu - Ossining NY, US
Robert Manzke - Sleepy Hollow NY, US
Raymond Chan - San Diego CA, US

KONINKLIJKE PHILIPS N.V. - EINDHOVEN

G01L 1/24

356 355

An optical detection tool employs a surgical end-effector () and an optical fiber (). In operation, the surgical end-effector () is navigated within an anatomical region relative to an object foreign to the anatomical region and the optical fiber () generates an encoded optical signal indicative of a strain measurement profile of the optical fiber () as the surgical end-effector () is navigated within the anatomical region. The optical fiber () has a detection segment in a defined spatial relationship with the surgical end-effector (). The strain measurement profile represents a normal profile in the absence of any measurable contact of the foreign object with the detection segment of the optical fiber (). Conversely, the strain measurement profile represents an abnormal profile in response to a measurable contact of the foreign object with the detection segment of the optical fiber ().

2013030, Nov 21, 2013

Jan 23, 2012

13/980905

Robert Manzke - Sleepy Hollow NY, US
Raymond Chan - San Diego CA, US
Gert Wim 'T Hooft - Eindhoven, NL
Adrien Emmanuel Desjardins - Waterloo, CA
Bharat Ramachandran - Morganville NJ, US

KONINKLIJKE PHILIPS N.V. - EINDHOVEN

G01B 11/24

356511

An integrated optical shape sensing system and method include an arrangement structure () configured to receive a fiber port or connector. A platform () is configured to provide a distance relationship with the arrangement structure such that the fiber port or connector is trackable to provide a location reference. The platform secures a patient in proximity to the arrangement structure. An optical shape sensing enabled interventional instrument () has a first optical fiber cable connectable to the fiber port or connector. An optical interrogation module () is configured to collect optical feedback from the instrument and has a second optical fiber cable connectable to the fiber port or connector such that a known reference position is provided for accurate shape reconstruction.

2013021, Aug 22, 2013

Oct 24, 2011

13/881179

Raymond Chan - San Diego CA, US
Jinnan Wang - Seattle WA, US
Adrien Emmanuel Desjardins - Waterloo, CA
Luis Felipe Gutierrez - Jersey City NJ, US
Maya Ella Barley - Walton On Thames, GB
Gert Wim 'T Hooft - Eindhoven, NL

KONINKLIJKE PHILIPS ELECTRONICS N.V. - EINDHOVEN

A61B 6/00

378 63

A system and method for adaptive imaging include a shape sensing system () coupled to an interventional device () to measure spatial characteristics of the interventional device in a subject. An image module () is configured to receive the spatial characteristics and generate one or more control signals in accordance with the spatial characteristics. An imaging device () is configured to image the subject in accordance with the control signals.

2013032, Dec 5, 2013

Feb 13, 2012

14/000415

Maya Ella Barley - Walton On Thames, GB
Adrien Emmanuel Desjardins - Waterloo, CA
Raymond Chan - San Diego CA, US
Gert Wim 'Thooft - Eindhoven, NL

KONINKLIJKE PHILIPS N.V. - EINDHOVEN

A61B 5/06, A61B 8/08, A61B 6/03, A61B 5/055, A61B 6/00, A61B 5/00

600409, 600424, 600417

A medical method and system include a medical imaging system () configured to generate images of an interventional procedure. An overlay generator () is configured to generate an overlay image on the images of the interventional procedure. An interventional device tracking system () is configured to track a three-dimensional position, orientation and shape of the interventional device during the procedure, wherein the overlay image is dynamically updated in response to deformations caused to an organ of interest by the interventional device during the procedure.

2014003, Feb 6, 2014

Mar 23, 2012

14/008187

Tobias Klinder - Uelzen, DE
Robert Manzke - Sleepy Hollow NY, US
Raymond Chan - San Diego CA, US

KONINKLIJKE PHILIPS N.V. - EINDHOVEN

A61B 6/03

600424

A system and method for shape sensing assistance in a medical procedure includes providing () a three-dimensional image of a distributed pathway system. A shape sensing enabled elongated device is introduced () into the pathway system. A shape of the elongated device in the pathway system is measured (). The shape is compared () with the three-dimensional image to determine whether a given path has been selected relative to a target.

2010009, Apr 15, 2010

Feb 7, 2008

12/526048

Robert Manzke - Ulm, DE
Raymond Chan - San Diego CA, US
Vivek Reddy - Boston MA, US
Andre Luiz Buchele D'avila - Boston MA, US

KONINKLIJKE PHILIPS ELECTRONICS N.V. - EINDHOVEN

A61B 5/05

600426

The present invention relates to a system () for determining a functional property of a moving object (), wherein the system () comprises a tag () contactable to the object () such that the tag () follows the movement of the object () and movement determination device () for determining the movement of the tag (). The system () comprises further a functional property determination device () for determining a functional property of the object () from the determined movement of the tag ().

2013031, Nov 28, 2013

Jan 24, 2012

13/981631

Bharat Ramachandran - Morganville NJ, US
Raymond Chan - San Diego CA, US
Robert Manzke - Sleepy Hollow NY, US

KONINKLIJKE PHILIPS N.V. - EINDHOVEN

A61B 5/06

600424

An optical shape sensing system employing an optical fiber () and one or more reference markers (). Each reference marker () has an identifiable reference tracking position within a reference coordinate system (). The optical fiber () has a reconstruction launch point ()within the reference coordinate system () serving as a basis for an execution of a shape reconstruction of the optical fiber () within the reference coordinate system (). The reconstruction launch point ()of the optical fiber () has a known spatial relationship with each reference marker () to facilitate an identification of the reconstruction launch point ()within the reference coordinate system ().