What Will Drive the Robotic Endoscopy Devices Market from 2024 to 2032.pdf

o Superior Ergonomics: Surgeons operate from a comfortable
console, reducing physical strain.
o Precision Control: Motion scaling (large hand movements
translated into tiny instrument movements).
• Current Market State (2024): The market is in a high-growth,
innovation-driven phase. Pioneering systems like Intuitive Surgical's
Ion (for bronchoscopy) and the increasing adoption of robotic
platforms for GI procedures (like Medtronic's Hugo RAS and Johnson
& Johnson's Monarch) have validated the technology. The market is
moving beyond laparoscopy into natural orifice applications.
Primary Growth Drivers: The Core Engines of
Expansion
a) Unmet Clinical Needs and Superior Patient Outcomes:
This is the most powerful driver. Robotic endoscopy addresses significant
limitations of conventional procedures.
• Accessing the Inaccessible: Robotic systems enable navigation to
previously hard-to-reach areas of the lung (peripheral nodules), bile
ducts, or deep within the colon, facilitating earlier and more accurate
diagnosis of cancers.
• Improving Diagnostic Accuracy: Enhanced stability and control
allow for more precise tissue sampling (biopsy), reducing false
negatives and the need for repeat procedures.
• Enabling Complex Therapeutics: Robotics is transforming
endoscopy from "see and sample" to "see and treat." It allows for
complex procedures like Endoscopic Submucosal Dissection (ESD)
for early-stage tumours to be performed with greater precision and
safety, often avoiding more invasive surgery.
b) The Demographics of an Aging Global Population:
The aging population is a massive, non-cyclical tailwind for the healthcare
sector.

• Rising Disease Prevalence: Older populations have a significantly
higher incidence of cancers (colorectal, gastric, lung),
gastrointestinal disorders, and other conditions requiring endoscopic
diagnosis and intervention.
• Demand for Minimally Invasive Options: An older, often co-morbid
patient population strongly prefers treatment options with less pain,
shorter hospital stays, and faster recovery the hallmark of robotic-
assisted procedures.
c) Technological Convergence and Product Innovation:
The technology itself is becoming more capable, accessible, and
integrated.
• Advancements in AI and Machine Learning: AI is being integrated
for procedural planning (identifying optimal paths to lesions), real-
time navigation (using pre-op CT scans as a map), and even lesion
detection (highlighting suspicious areas for the physician).
• Improved Haptics and Visualization: While a challenge, the
development of advanced haptic feedback and 3D high-definition
imaging provides surgeons with a more immersive and intuitive
experience.
• Miniaturization and Single-Use Instruments: Development of
smaller, more flexible robots and the shift to single-use, sterile
instruments reduce cross-contamination risk and simplify hospital
logistics.
d) Strong Support from the Clinical Community:
Surgeons and gastroenterologists are key adoption influencers.
• Overcoming the Learning Curve: Robotic systems can standardize
complex procedures, potentially reducing the variability between
surgeons and making advanced techniques accessible to a broader
range of practitioners.
• Ergonomics and Physician Longevity: The ergonomic benefits
reduce physical strain, helping to extend the careers of skilled
endoscopists and prevent work-related musculoskeletal injuries.

e) Favourable Reimbursement and Healthcare Economics:
As evidence mounts, payers are increasingly recognizing the value.
• Growing Reimbursement Codes: Regulatory bodies like the CDC in
the US are establishing specific CPT codes for robotic-assisted
endoscopic procedures, which is critical for hospital adoption.
• Demonstrating Value-Based Care: While the initial capital cost is
high, robotic systems can demonstrate value by reducing procedure
times, complication rates, hospital stays, and the need for more
expensive surgical interventions down the line.
Key Trends Shaping the Market's Evolution (2024-
2032)
a) The Platform Approach vs. Single-Use Systems:
The market will see a battle between:
• Multi-Specialty Platforms: Large companies (like J&J, Medtronic,
Intuitive) are developing robotic platforms that can be used across
bronchoscopy, gastroenterology, and urology with different modules
and instruments.
• Specialized, Single-Use Robots: Emergence of smaller companies
focusing on disposable, procedure-specific robotic devices that
lower the initial capital barrier for hospitals.
b) Integration with Surgical Robotics and the Operating Room:
Robotic endoscopy will not exist in a silo. The trend is toward:
• Hybrid Procedures: Combining robotic endoscopic approaches with
laparoscopic or surgical robotic systems for comprehensive
treatment.
• The Connected OR: Robotic endoscopy data (video, navigation
paths) will be integrated with hospital EHRs and PACS systems,
creating a digital record for better patient care and data analytics.
c) Expansion into New Clinical Applications:
The application scope will broaden significantly beyond current uses:

• Neuroendoscopy: For minimally invasive brain and spinal
procedures.
• Cardiac Procedures: For interventions within the heart and
vasculature.
• Bariatric Endoscopy: For new, incisionless weight-loss procedures.
d) Data as an Asset:
The procedures generate vast amounts of data, which will be used for:
• Surgical Training and Simulation: Creating digital twins of
procedures for training.
• Predictive Analytics: Using AI to predict patient outcomes based on
procedural data.
• Clinical Research: Aggregating anonymized data to refine best
practices and develop new techniques.
Market Challenges and Restraints
• High Capital and Operational Expenditure: The significant upfront
cost of the system and the ongoing expense of proprietary
instruments and maintenance are a major barrier, especially for
smaller hospitals and ambulatory surgical centers.
• Reimbursement Uncertainties: While improving, reimbursement
rates do not always fully cover the cost of the technology, creating
financial uncertainty for healthcare providers.
• The Learning Curve: Despite ergonomic benefits, surgeons still
require dedicated training to achieve proficiency, which can
temporarily slow down adoption.
• Regulatory Hurdles: Gaining regulatory approval (from the FDA, CE,
etc.) for new devices and indications is a complex, time-consuming,
and costly process.
• Competition from Advanced Manual Techniques: Improvements in
traditional endoscope technology, such as motorized drives and
better imaging, provide a lower-cost alternative for some procedures.

Conclusion: The 2032 Outlook
By 2032, robotic endoscopy will be a cornerstone of minimally invasive
care. The market will be characterized by:
1. Segmentation and Specialization: A tiered market with multi-
purpose platforms in large academic hospitals and specialized,
lower-cost robots in community settings.
2. The Autonomous Assistant: AI will evolve from a navigation aid to a
semi-autonomous co-pilot, capable of executing certain parts of a
procedure under surgeon supervision.
3. Mainstream Adoption: Robotic-assisted procedures will become
the standard of care for an expanding list of indications in
pulmonology, gastroenterology, and beyond.
4. Value-Based Justification: The conversation will shift from cost to
comprehensive value, with robotic endoscopy proven to improve
long-term patient survival and quality of life while optimizing overall
healthcare spending.
In essence, the growth of the robotic endoscopy market is not just about
automating a procedure; it's about fundamentally enhancing human skill
to enable earlier, more accurate, and less traumatic interventions,
ultimately improving the standard of care for millions of patients
worldwide.
Source: https://www.credenceresearch.com/report/robotic-endoscopy-
devices-market