Development of the ROBODOC® System for Image-Directed Surgery · • Total Hip and Knee...
Transcript of Development of the ROBODOC® System for Image-Directed Surgery · • Total Hip and Knee...
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Development of the ROBODOC® System forImage-Directed Surgery
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Peter Kazanzides
• Ph.D. EE, Brown University (Robotics), 1988• Post-doc at IBM T.J. Watson Research Ctr., 1989• Visiting Engineer at UC Davis, 1990• Founder and Director of Robotics and Software at
Integrated Surgical Systems, 1990-2002• Chief Systems and Robotics Engineer at JHU
ERC for CISST• Assistant Research Professor, Computer Science
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Outline• Application Overview• Registration Methods• ROBODOC History (Design Iterations)
– Design goals– System description– Safety systems– Lessons learned
• Summary
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Application Overview
• Total Hip and Knee Replacement Surgery– replace damaged articulating surfaces with
implants• cemented - use cement to attach to bone• cementless - rely on bone ingrowth
– position/orientation is important– proper fit can be important (cementless)
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Hip and Knee Implants
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Total Hip Replacement Surgery
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ROBODOC Video (1991)
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Current Technique for THR
• Pre-operative planning using X-rays and acetate overlays
• Surgical preparation using mallet and broach or reamer
• Relies on surgeon’s “feel”
• Outcome depends on surgeon experience
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ROBODOC THR Procedure
• Pre-operative planning using 3-D CT scan data and implant models (ORTHODOC®)
• Surgical preparation of bone by robot using milling tool– Increased dimensional accuracy– Increased placement accuracy
• Outcome more consistent
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Manual Broach vs. Robot
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ROBODOC Procedure Overview
• Perform orthopedic procedures (hip and knee replacement):– Preoperative CT scan– Preoperative planning– Intraoperative registration– Robotic machining of bone
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What is Registration?
• Establishing a transformation (conversion) from one coordinate system to another– CT coordinates (preoperative plan)– Robot coordinates (surgery)
Allows the robot to cut the implant in the position planned by the surgeon.
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Simple Registration Method
• Use reference points (fiducials) that can be seen in each coordinate system
• Simple example: using a map
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How Many Points Do You Need?• 2D world has 3 degrees of freedom
– X, Y, θ
• 3D world has 6 degrees of freedom– X, Y, Z, Rx, Ry, Rz
For 2-D:
1 point (x1,y1) is not enough
2 points (x1,y1), (x2,y2) is more than enough
Redundant information: distance between points
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ROBODOC Example• Using 3 reference points (fiducials)
2
3
1
T2
Y
X T1
X
Y
Z
YZ
X
T2-1 * T1
Q: Are 3 points needed?
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Mathematical Basis
• Define a fiducial coordinate system by some convention, e.g.,– X is unit vector from Point 1 to Point 2– Y is unit vector that is perpendicular to X and
points towards Point 3.• Each observer (CT/Orthodoc and Robot)
finds fiducials in its own coordinate system and computes transformation (T1 and T2).
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Mathematical Basis (Cont.)
• Use T1 to convert implant position from CT coordinate system to fiducial coordinate system.
• Use T2-1 to convert implant position from fiducialcoordinate system to Robot coordinate system.
• By combining transformations (T2-1 * T1), we can determine the transformation between the CT and Robot coordinate systems.– Key result for surgical navigation and robotics!
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Alternate Computation
Define: A = T2-1 * T1PR = A * PCT
Given 3 points P1, P2, P3 that are located in Robot and CT coordinates, solve simultaneous equations for A
(e.g., least-squares estimation)
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ROBODOC Pin-Based Registration
• Surgery to implant pins (bone screws) prior to CT• Planning software detects pins in CT coordinates• Robot finds pins in Robot coordinates• Software checks pin distances (safety check) and
then computes transformation between CT coordinates and robot coordinates
• Software uses transformation to convert planned implant position (CT coordinates) to surgical position of bone (Robot coordinates)
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Pin-Based Registration
• Q: How many pins are needed?
• A: Need at least 3 “features”– 3 Pin Registration: uses center of each pin– 2 Pin Registration: uses center of each pin and
axis of one pin
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Pin-Based Registration
+ Easy to implement
+ Easy to use
+ Very accurate (if pins far enough away)
+ Very reliable
- Requires extra surgery
- Causes knee pain in many patients
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Harder Registration Method
• If there are no easily identifiable features, must find another way to establish correspondences
• Example: finding a known object in the dark by probing
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ROBODOC Pinless Registration
• More complex (point-to-surface matching)• Surgeon creates surface model of bone from
preoperative CT (semi-automatic software).• Surgeon uses digitizing device to collect
bone surface points intraoperatively.• Software ensures good distribution of points• Surgeon verifies result
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Intraoperative Point Collection
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Pinless Registration
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Handling Re-Registration
• Problem: How to re-register if bone moves during procedure?– Required bone surfaces may have been
machined away– Pinless registration can be time-consuming
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Handling Re-Registration
Solution: Implant markers (pins) during surgery.
1. Expose femur and implant markers2. Perform pinless registration3. Locate markers4. Use pinless registration result to transform marker
positions to CT coordinates5. Start cutting implant cavity6. If motion occurs, use pin-based registration
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Pinless Video (1998)
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ROBODOC History1986-1988 Feasibility study and proof of
concept at U.C. Davis and IBM
1988-1990 Development of canine systemMay 2, 1990 First canine surgery
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ROBODOC History1990-1995 Human clinical prototype
Nov 1, 1990 Formation of ISS
Nov 7, 1992 First human surgery, Sutter General Hospital
Aug 1994 First European surgery, BGU Frankfurt
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ROBODOC History (cont.)1995-2002 ROBODOC as a Medical Product
March 1996 CE Mark (C System)April 1996 First 2 installations (Germany) Nov 1996 ISS initial public offering (NASDAQ)Sept 1997 IMMI acquisition (Neuromate)March 1998 First pinless hip surgeryApril 1999 New electronics design (D System)Feb 2000 First knee replacement surgery
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ROBODOC Generations
• Alpha: Canine System (1990)• Beta: Human clinical prototype
– Version 1: 10 patient study (1992)– Version 2: Multi-center trial (1993)
• Commercial Product– C System: First version (1996)– D System: Custom electronics (1999)
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Canine System Goals• Proof of concept
– procedural flow– high accuracy (small bones)– operating room compatibility (sterility)
• Focus on application, not system design– Use primarily off-the-shelf hardware
• Rely on engineering supervision in OR• Research mode: no formal design process
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Canine System Design
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Canine System Design
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Canine System Design
• Prototype appearance (external cables, etc.)• Primitive (text-based) user interface
– Engineer operated robot for all 26 surgeries– Graphical display during cutting (RTM)
• Software written in AML• Primitive computer hardware (286/386)• Did not use some safety systems in surgery
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Canine System Safety
• Force sensor to detect collisions• Optical tracking system (Optotrack) to
independently track robot end-effector– not used clinically
• Bone motion monitor– design not completed
• Visualization of cutting procedure (RTM)– display cut paths on CT cross-sections
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First Surgery - May 2, 1990
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Canine System Lessons
• The procedure works!• The user interface needs improvement• Error recovery can be complex• Bone motion detection is critical• Avoid special power requirements
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Beta System Goals
• Re-design system for production– Create specifications, risk analysis, etc.– Improve system appearance– Rewrite software in industry-standard language
• Create user interface for surgeon use– graphical user interface and simple pendant
• Support longer tools (higher stiffness)• Reduce cost
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Beta System Design
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Beta System Design
• Customized industrial robot (Sankyo Seiki)– Integrated pitch axis– Integrated redundant encoders– Improved stiffness (roll axis)– Reduced force and speed for safety– High accuracy specifications
• Adjustable base to increase workspace
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Beta System Design
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Beta System Design
• Significantly improved appearance– Still a few external cables
• Graphical user interface and pendant• Software written in C and C++• Additional safety features• Improved error handling software
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Safety Design Overview
• Driven by risk analysis (FMECA)– Eliminate single points of failure
• Fail Safe design– System fails to a safe state (robot powered off,
finish procedure manually)• Limited Fault Tolerance
– System can continue without RTM graphics• Completely different from industrial robots
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Beta System Safety Design
• Force sensor to detect collisions• Visualization of cutting procedure (RTM)• Redundant joint encoders
– primary encoders on motor shaft– redundant encoders at joint
• Bone motion monitor (intraoperative)• Bone motion detection during CT scan
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Beta System Safety Design• Safety Volume
– Independent check that tool is in implant cavity • Startup Diagnostics
– Verify force sensor, robot, BMM• Mechanical changes to robot
– higher gear ratios to reduce speed– smaller motors to reduce torque
• Low-level software speed limit
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First Surgery - Nov 7, 1992
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The Press Reacts...
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Beta System Lessons• Did not meet EMC requirements
– Emissions marginal– Susceptible to interference (cautery mode)
• Required larger vertical workspace– Version 2 system had base encoder
• Difficult to move robot• System too large for OR
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Commercial System Goals
• Meet regulatory requirements– CE Mark– UL/CSA
• Improve maneuverability• Reduce size• Improve system appearance• Support local languages
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Quality Systems
• “Design controls” are now required– By FDA (GDP)– For ISO9000 certification
• Regulatory agencies do not prescribe QS– Company defines Quality System– Regulatory agency certifies Quality System and
monitors compliance (Quality Records)
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Quality System Documents
• Project Plan• Software Development Procedure• Software Quality Assurance Plan• Risk or Hazard Analysis• Requirements Specifications• Verification and Validation Plan• Change Control Procedures
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Commercial System Design
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Commercial System Design
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Commercial System Design
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Commercial System Design
• Distributed architecture– EMC compliance
• Two units (Robot and Control Cabinet)• More attractive robot and base
– Force sensor cable inside robot arm• Base easier to maneuver
– Steering system
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Commercial System Safety Design
Safety design reviewed by notified body (TUV) for CE mark
• Electrical safety requirements• Electromagnetic emissions/susceptibility• Risk Analysis
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Commercial System Surgery
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Commercial System Lessons
• Robot should either save time (money) or provide substantial clinical benefit (enable new procedures).
• Robot must interface with other devices in the operating room of the future.
• Registration should not require an additional surgery.
• Further size reduction is necessary.
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ROBODOC Status
• Approximately 50 systems installed worldwide– Europe (Germany, Austria, Switz., France,
Spain)– Asia (Japan, Korea, India)– U.S. (Clinical trial for FDA approval)
• Over 10,000 hip replacement surgeries• Several hundred knee replacement surgeries
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Total Knee Surgery (2000)
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Summary
• The ROBODOC System has evolved over the past 15+ years:– Laboratory prototype– Canine system– Clinical prototype– Commercial product
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Summary
• Experience has led to changes in:– System architecture (distributed)– Safety design (risk analysis)– User interface (ease of use)– Ergonomics (OR compatibility)
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ROBODOC Video (1995)