Image Guidance Laboratories, Stanford University School of Medicine Jacqueline Nerney Welch, Jeremy A. Johnson, Michael R. Bax, Rana Badr, Ramin Shahidi

Image Guidance Laboratories, Stanford University Image Guidance Laboratories, Stanford University School of MedicineSchool of Medicine

Jacqueline Nerney Welch, Jeremy A. Johnson, Michael R. Bax, Rana Badr, Ramin Shahidi

IEEE Ultrasonics Symposium 2000

October 24, 2000

A Real-time Freehand 3D Ultrasound System for Image-guided Surgery


Overview

• Design motivations and decisions– 3D ultrasound

– Freehand scanning

– Optical tracking

– Volume rendering

– Simultaneous acquisition and visualization

• Methods– Equipment

– Spatial calibration

– Volume construction and maintenance

• Results

• Future Work


Ultrasound

• Ultrasound versus other imaging modalities (CT, MR, X-ray)– Least expensive

– No ionizing radiation

– Compatible with existing surgical instruments

– Widely available and commonly used

– Real-time, interactive nature


3D Visualization of Ultrasound

• Compared to 2D, 3D provides:– More intuitive and comprehensible images

– More accurate volume estimation

– Shorter scanning times

– Improved sharing of information

2D Ultrasound Image Volume Rendered 3D US


3D from Conventional 2D Ultrasound

Volume Volume Construction Construction

EngineEngine

WorkstationWorkstation

Volume Volume Rendering Rendering

EngineEngineji

k

(x,y,z)

2D Images

Position Data

US Probe

Tracking Device


Optically Tracked Freehand Acquisition

• Freehand versus other scanning techniques (mechanical)– Greatest freedom of movement

– Compact

– Least cumbersome

– Requires probe position measurements

• Optical versus other position tracking methods (magnetic, mechanical, speckle decorrelation)– Insensitive to metallic surgical equipment

– Allows volume localization


• Volume rendering versus other visualization methods (slice projection, surface rendering)– Truest to the data set

– Easiest to interpret

– Segmentation not required

– Computationally expensive but feasible with current technology

Interactive Volume Rendering


Volume Construction

Engine

Visualization

Static Volume

Simultaneous Acquisition & Visualization

(x,y,z)

ji

k

DataStorage

Acquisition

(x,y,z)

ji

k

Volume Construction

Engine

Simultaneous Acquisition & Visualization

Dynamic Volume


Equipment

• Image Guided Technology FlashPoint™ 5000 optical tracking system with 580 mm camera

• Sonosite handheld ultrasound scanner with 5MHz linear probe

• SGI 320 Visual Workstation with a single processor running Windows NT


Image to Volume Mapping

SSPPTTWW pTTTp

IISS pSp

WWVV pSp


Calibration Parameters

• 6 extrinsic parameters

– Rotation (Ri , Rj , Rk)

– Translation (ti , tj , tk)

• 2 intrinsic parameters

– Image scale (si , sj)

• Can be written as

jS, v

iS, u

Slice Coordinates

Probe Tracking Device Coordinates

iP jP

kP

v

uj

i

S

PSSPSP

p

ps

s

00

0

0

x

txRx

(Ri , Rj , Rk)(ti , tj , tk)(si , sj)


Calibration Phantom

Ultrasound Phantom(1/16” Acrylic)

Image of Phantom During Calibration


Calibration Method

• Obtain feature positions• Align ultrasound probe• Capture US image and probe position• Localize features in image• Calculate calibration parameters

• Scale factor

• Rotation and Translation


Volume Construction and Maintenance

Insertion of New Slices Removal of

Old Slices

Overwrite Existing Slices

Interpolate with Nearby

Slices


Results


Results


Future Work

• Quantify and improve system performance– Spatial and temporal accuracy

– Data rates

• Display position and trajectory of surgical instruments

• Apply system to clinical situations


Acknowledgements

• Dr. Thomas Krummel’s lab• DOD Graduate Research Fellowship• CBYON, Inc.

Documents

Image Guidance Laboratories, Stanford University School of Medicine Jacqueline Nerney Welch, Jeremy A. Johnson, Michael R. Bax, Rana Badr, Ramin Shahidi