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1. | EXECUTIVE SUMMARY |
1.1. | Report scope |
1.2. | Sectors of robotic surgery covered in this report |
1.3. | Drivers of the surgical robots market |
1.4. | Why use robotic surgery? |
1.5. | Limitations & barriers to adoption |
1.6. | Mergers & acquisitions in the robotic surgery space |
1.7. | Investments into robotic surgery companies |
1.8. | Intuitive Surgical - Key numbers |
1.9. | Robotic general surgery - Emerging competitors of da Vinci |
1.10. | Conclusions and outlook - Robotic general surgery |
1.11. | Robotic catheter and endoscope navigation |
1.12. | Conclusions and outlook - Robotic catheter navigation |
1.13. | Robotic positioning of surgical tools |
1.14. | Conclusions and outlook - Robotic positioning of surgical tools |
1.15. | Robotic intra-operative camera manipulation |
1.16. | Conclusions and outlook - Robotic intra-operative camera manipulation |
1.17. | Market Analysis 2015-2030 |
1.18. | Report summary |
1.19. | Robotic surgery's multiple benefits have fuelled its rise |
1.20. | Inherent limitations and conceptual flaws have blocked it |
1.21. | Competing directly with Intuitive Surgical is highly risky |
1.22. | Where do the market opportunities lie? |
1.23. | Does the concept of remote surgery live up to the hype? |
1.24. | Opportunities for improvement |
2. | INTRODUCTION |
2.1. | Report scope |
2.2. | Open surgery |
2.3. | Minimally invasive surgery considerably improves recovery time |
2.4. | Keyhole surgery has non-negligible limitations |
2.5. | What is robotic surgery? |
2.6. | History of robotic surgery: an overview |
2.7. | Early history of robotic surgery |
2.8. | What operations are surgical robots used for? |
2.9. | Drivers of the surgical robots market |
2.10. | Why use robotic surgery? |
2.11. | Robotic surgery provides enhanced vision |
2.12. | Limitations & barriers to adoption |
2.13. | Why are surgical robots so expensive to purchase? |
2.14. | Regulations & path to market: EU |
2.15. | Regulations & path to market: USA |
2.16. | Mergers & acquisitions in the robotic surgery space |
2.17. | Investments into robotic surgery companies |
2.18. | Sectors of robotic surgery covered in this report |
3. | ROBOTIC GENERAL SURGERY |
3.1. | How does robotic general surgery work? |
3.2. | Flexible robotic end effectors |
3.3. | Types of procedures performed by general surgery robots |
3.4. | Investments into robotic general surgery companies |
3.5. | Intuitive Surgical - The pioneer of robotic surgery |
3.6. | Intuitive Surgical - Key numbers |
3.7. | da Vinci Surgical System |
3.8. | Approved procedures for da Vinci |
3.9. | Virtual simulations for robotic surgery training |
3.10. | Emerging competitors of da Vinci |
3.11. | Following the da Vinci approach |
3.12. | Example: TransEnterix |
3.13. | Example: Avatera |
3.14. | Example: CMR Surgical |
3.15. | Example: Titan Medical |
3.16. | Example: Medtronic |
3.17. | Flexible arms |
3.18. | Example: Medrobotics |
3.19. | Example: Korea Advanced Institute of Science and Technology (KAIST) |
3.20. | Wearable robotic tool for surgery |
3.21. | Downsizing surgical robots |
3.22. | Example: Virtual Incision |
3.23. | Example: Hong Kong Polytechnic University |
3.24. | Example: Microsure |
3.25. | Combining conventional and robotic general surgery |
3.26. | Example: Galen Robotics |
3.27. | Example: Distalmotion |
3.28. | Example: Preceyes |
3.29. | Handheld, mechanical instruments as an alternative to computer-aided surgery |
3.30. | Example: FlexDex Surgical |
3.31. | Example: Human Xtensions |
3.32. | State of development of robotic general surgery systems |
3.33. | Summary and outlook |
4. | ROBOTIC CATHETER AND ENDOSCOPE NAVIGATION |
4.1. | What are catheters and endoscopes? |
4.2. | Robotic navigation of medical instruments |
4.3. | Advantages of robotic navigation systems |
4.4. | Types of intervention |
4.5. | How does the wire move? |
4.6. | Investments into robotic catheter navigation companies |
4.7. | Key players |
4.8. | Intuitive Surgical |
4.9. | Example: Auris Health |
4.10. | Corindus Vascular Robotics |
4.11. | Robocath |
4.12. | Moray Medical |
4.13. | Autonomous active steering: Fraunhofer IPA |
4.14. | Autonomous active steering: Harvard Medical School |
4.15. | Magnetic steering |
4.16. | Magnetic steering: Stereotaxis |
4.17. | Magnetic steering: Massachusetts Institute of Technology |
4.18. | Magnetic steering: Polytechnique Montréal |
4.19. | State of development of robotic catheter navigation systems |
4.20. | Summary and outlook |
5. | ROBOTIC POSITIONING OF SURGICAL TOOLS |
5.1. | Robotic guidance and positioning |
5.2. | Investments into robotic instrument positioning companies |
5.3. | Sectors and key players |
5.4. | Robotic orthopaedic surgery |
5.5. | Key components of robotic orthopaedic systems |
5.6. | Pre-operative software for procedure planning |
5.7. | Robotic arm holding the instrument |
5.8. | 3D cameras for real time instrument tracking |
5.9. | Example: Stryker |
5.10. | Example: Medtronic |
5.11. | Example: Zimmer Biomet |
5.12. | Example: Smith & Nephew |
5.13. | Example: Brainlab |
5.14. | Example: Orthotaxy |
5.15. | Example: Globus Medical |
5.16. | Example: Curexo |
5.17. | Example: Eindhoven Medical Robotics |
5.18. | Comparison of robotic orthopaedic surgery systems |
5.19. | Why do large orthopaedic companies seek to acquire surgical robots? |
5.20. | Robotic neurosurgery |
5.21. | Example: Renishaw |
5.22. | Example: Kuka Robotics |
5.23. | Example: AiM Medical Robotics |
5.24. | Robotic positioning for laser therapy |
5.25. | Example: Kuka Robotics |
5.26. | Example: Zeiss VisuMax |
5.27. | Robotic biopsy |
5.28. | Example: XACT |
5.29. | Example: Machnet Medical Robotics |
5.30. | State of development of robotic surgical tool positioning systems |
5.31. | Summary and outlook |
6. | ROBOTIC SYSTEMS FOR INTRA-OPERATIVE CAMERA MANIPULATION |
6.1. | Robotic intra-operative camera manipulation |
6.2. | Investments into companies developing intra-operative camera manipulation robots |
6.3. | Robotic laparoscope holders |
6.4. | Example: AKTORmed |
6.5. | Example: OR Productivity |
6.6. | Example: Storz |
6.7. | Robotic intra-operative imaging and microscopy |
6.8. | Example: Brainlab |
6.9. | Example : Zeiss |
6.10. | Example: Synaptive Medical |
6.11. | State of development of robotic intra-operative camera manipulation systems |
6.12. | Summary and outlook |
7. | ARTIFICIAL INTELLIGENCE IN ROBOTIC SURGERY SYSTEMS |
7.1. | Terminologies explained |
7.2. | AI enables human-robot interaction |
7.3. | AI facilitates image-guided robotic surgery |
7.4. | Challenges of using AI for pre-operative planning |
7.5. | Challenges of AI-driven robotic instrument positioning |
7.6. | AI in robotic surgery: Legal and regulatory landscape |
8. | HAPTIC FEEDBACK MECHANISMS IN ROBOTIC SURGERY SYSTEMS |
8.1. | Surgeons must 'sense' what they are doing |
8.2. | Haptics in robotic surgery |
8.3. | Haptics enhance robotic surgery systems |
8.4. | Components of haptic feedback mechanisms |
8.5. | How is haptic feedback achieved? |
8.6. | What types of sensors are used? |
8.7. | Haptic mechanisms: Challenges for robotic surgery |
9. | MARKET ANALYSIS |
9.1. | Chapter overview |
9.2. | Methodology |
9.3. | The number of robotic surgery companies will rise exponentially in the next decade |
9.4. | Historical revenue data - Robotic surgery |
9.5. | Forecast 2020-2030 - Robotic surgery |
9.6. | Historical revenue data - Robotic general surgery |
9.7. | Historical revenue - Intuitive Surgical |
9.8. | Intuitive Surgical da Vinci systems sold |
9.9. | Forecast 2020-2030 - Robotic general surgery |
9.10. | Historical revenue data - Robotic catheter navigation |
9.11. | Forecast 2020-2030 - Robotic catheter navigation |
9.12. | Historical revenue data - Robotic surgical tool positioning |
9.13. | Forecast 2020-2030 - Robotic surgical tool positioning |
9.14. | Robotic intra-operative camera manipulation: Market share in 2019 |
9.15. | Forecast 2020-2030 - Robotic intra-operative camera manipulation |
10. | CONCLUSIONS |
10.1. | Report summary |
10.2. | Robotic surgery's multiple benefits have fuelled its rise |
10.3. | Inherent limitations and conceptual flaws have blocked it |
10.4. | Competing directly with Intuitive Surgical is highly risky |
10.5. | Where do the market opportunities lie? |
10.6. | Does the concept of remote surgery live up to the hype? |
10.7. | Opportunities for improvement |
11. | COMPANY PROFILES |
Slides | 216 |
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Forecasts to | 2030 |