Laparoscopic Surgery Training System MediTronics Inc. CEO Alexander Hahn CTO Mark Jung CFO Han-Lim Lee April 2007
Roles in Project Alexander Hahn (CEO) - Software developer, Technical writing Mark Jung (CTO) - Software and Hardware developer, Finance Management Han-Lim Lee (CFO) - Hardware developer, Time management
Presentation Outline Background Goals Proposed Solution System Overview Hardware Software Business Case Budget/Timeline Conclusion
What’s Laparoscopic Surgery? Minimally invasive surgery Gas-inflated abdomen Laparoscope and tools
Why Laparoscopic Surgery? Small incision Speed up recovery times Minimize post- operative pain Reduce the chances of infection Minimize the size of scars
The Problems Unusual surgery environment
The Problems Difficulty in use of the tools
Current Systems in the market Pure simulation software - Limitation in getting hands-on experience - Lack of physical feeling Pure physical training system - No automated feedback - Eye examination required
Goals Providing an physical training system Providing an automated feedback & evaluation system A hybrid training system of physical and virtual feature
System Overview SurgiBox Computer
System Overview Tools
System Overview FSR sensor
System Overview Sensor feedback circuitry
System Overview Moving task
System Overview Cutting task
System Overview Suturing task
Overall System
Hardware Outline Hardware System Overview Force during surgeries FSR vs Strain Gauge FSR Verification Transmitter and Receiver Circuit Alternative Design Option Possible Future Work
H.W. System Overview
Force During Surgeries Highest Force Peak = 2.3 N Lowest Force Peak = 0.2 N For liver, as low as 0.05 N s_2003_MIS_sensor_extended.pdf.
Force Limit Maximum Force measured to tear off beef 2.0 N ( 0.2N < 2.0N <2.3N) 2.0 N is set as a force limit and correspond to 2.9 Volt in the system.
Force Sensing Resistor How to measure force? VS FSR Strain Gauge
Force Sensing Resistor Advantage: Cheaper Ideal for our system Advantage: Smaller in Size Disadvantage: Bigger than Semi- conductor S.G. FSR Disadvantage: Strain Changes without Gripping Strain Gauge
FSR Verification FSR 400 is used and currently the smallest fsr in the market Force (g) Resistance (kOhm) Day1Day2Day
FSR Verification
Transmitter and Receiver Transmitter Side: Force on the gripper is compared with our limit force (2.9V) Analog to digital conversion Transfer signal serially to the receiver
Transmitter and Receiver Transmitter Side:
Transmitter and Receiver Receiver Side: Transfer the received data to pc through serial port Receives signal from transmitter when limit exceeds
Transmitter and Receiver Receiver Side:
Transmitter and Receiver Transmitter connected with tool
Transmitter and Receiver FSR attached on tool tip
Transmitter and Receiver Transmitter from top-view
Transmitter and Receiver Receiver with serial port connected
Alternative Design Option Without using RF module
Alternative Design Option Use PCB instead of Vector Board
Future Work - Hardware Use both FSR and Strain Gauge Research and experiment on real human tissue for setting force limit Varying force limit according to different surgery types PCB instead of vector board Research on smaller FSR or other components to measure force
Test Program – Moving Task Before moving task After moving task
Test Program – Cutting Task Before cutting task After cutting task
Test Program – Suturing Task Before suturing task After suturing task
Image Processing Final Solution : Colour Quantization Simple Effective
User Interface Simple Interface Main Control “The Green Arrow”
User Interface Task Selection Very Basic Controls
User Interface Task Mode
Evaluation Performance time – timer in the test program Gripping force – FSR sensor Accuracy – Image processing
Evaluation Quality > Speed
Problems Encountered Difficult Programming Language MFC Serial Data Collection FSR Sensor Data Image Processing Colours Complexity
Future Work - Software Modifying our test programs - providing random shape for cutting - various target locations for moving Add new test programs - Knot tying - Suction Add more feedback sensors - Checking tightness of suturing/tying task
Budget ComponentCost SugiBox and surgical toolsSFU Robotics Lab ComputerSFU Robotics Lab LaparoscopeSFU Robotics Lab Vector boards$24.00 Chip components$15.00 & SFU Robotics Lab CCD board camera$ FSR sensors$30.59 Batteries and holders$23.84 Color paper, needle and tapes$15.00 Total$208.43
Market Plan Target market - Hospital - Medical school - Research Laboratory Provide an on-site training
Competitors Simulab Corporation Physical training system with digital camera (excluding PC) $ opicSurgery.htm
Competitors Simulab Corporation LabTrainer Skill Set $ opicSurgery.htm
Cost and Selling Price Estimated Cost - Hardware (SurgiBox, camera, tools, surgical models, circuits, sensors) ~ $250 - Software (Test & Evaluation program) ~$200 Selling Price - Unit selling price of ~ $585 with 30% of margin - Much lower than Simulab Corporation products ($ 2020) - Providing both physical and virtual system product
Timeline - Project Schedule Gantt Chart Planned on January 2007
Timeline - Project Schedule Revised Schedule Planned on March Project Completed by Apr.10 th, 2007 Final Schedule on Project completion - Actual Project Completion on Apr.16 th, 2007
Timeline - Project Schedule Main factors that caused delay - Hardware and software interface - Longer integration time than expected - Image processing complexity
Team Work Very Few Conflicts Good Communication Even Work Distribution Modulated Tasks Good Mix of Skill Sets Respect
What We Learned (Technical) Background knowledge in laparoscopic surgery - Research works in Dr. Payandeh’s Robotics Research Lab - CESEI Tour and meeting with Dr. Qayumi - Research from papers and webs Hardware - Microcontroller (PIC), RF transceiver, Voltage converter and Circuit design, PIC programming in Assembly Software - MFC - Serial port data reading in C++ - OpenCV and GDI+ Image Processing in C++
What We Learned (Team) Plan the whole project term Plan the project by month Plan the project by week Plan the project by day Go back up the ladder and make changes where necessary
Acknowledgements Supervisor SFU Robotics Lab Dr. Shahram Payandeh CESEI, Director Dr. Karim Quyami SFU Alumni Wayne Chan
The End Questions ?