한글목차

VR 수술 트레이닝 시장은 2024년에는 3억 4,527만 달러에 달하며, 2025년에는 4억 1,204만 달러, CAGR 19.89%로 성장하며, 2030년에는 10억 2,546만 달러에 달할 것으로 예측됩니다.

차세대 수술 훈련, 기술 개발 형성에 있으며, 몰입형 VR 플랫폼의 중요한 역할을 이해

VR 기술은 연수생들이 중요한 수술 기술을 개발할 수 있는 몰입감 있고 위험 부담이 없는 환경을 구축함으로써 외과 교육의 전망을 빠르게 재구성하고 있습니다. 의료 기관과 교육 센터는 이론적 학습과 현장 실습 사이의 간극을 메우기 위해 이러한 플랫폼을 커리큘럼에 통합하는 경우가 늘고 있습니다. 최소침습수술과 로봇수술이 복잡해짐에 따라 고충실도 피드백, 재현 가능한 시나리오, 데이터베이스 성과 지표를 제공하는 시뮬레이션 시스템에 대한 수요도 증가하고 있습니다. 이러한 변화는 의료진이 수술실에 들어가기 전에 숙련도를 높여 환자의 안전을 강화해야 한다는 의료계의 광범위한 요구를 반영하고 있습니다.

VR 혁신으로 수술 훈련의 변화를 촉진하고, 기술, 교육, 규제 측면에서 중요한 변화의 필요성을 확인

급속한 기술 발전, 교육 패러다임의 변화, 규제 기준의 진화는 외과 교육에 대한 생각과 제공 방식의 근본적인 변화를 총체적으로 촉진하고 있습니다. 머신러닝 알고리즘과 몰입형 시뮬레이션 환경의 통합은 훈련생의 성과에 동적으로 반응하는 적응형 학습 경로를 가능하게 하여 기술 습득을 가속화합니다. 동시에 의과대학과 교육병원에서는 기존의 시간 기반 모델 대신 역량 기반 평가에 중점을 둔 커리큘럼 재설계가 이루어지고 있으며, 이는 결과 중심 교육으로의 광범위한 전환을 반영하고 있습니다.

2025년 미국의 새로운 관세가 VR 수술 교육 생태계와 공급망에 미치는 종합적인 영향 평가

2025년 미국의 새로운 관세 부과로 인해 수술 훈련 플랫폼에 사용되는 VR 하드웨어 구성 요소 및 주변 기기의 세계 공급망에 파문이 일고 있습니다. 헤드 마운트 디스플레이, 컴퓨팅 장치, 특수 촉각 기기 제조업체는 수입 비용 상승에 직면하여 많은 제조업체가 국제 조달 전략을 재검토해야 하는 상황에 직면해 있습니다. 이에 대응하기 위해 일부 주요 하드웨어 개발 기업은 비용 상승을 완화하기 위해 지역 제조 파트너십을 시작하거나 관세가 면제되는 관할권으로 조립 라인을 옮기고 있습니다.

VR 수술 교육의 구성 요소, 기술, 교육 모듈, 최종사용자별 주요 시장 세분화에서 실용적인 인사이트를 얻을 수 있습니다.

시장 역학에 대한 인사이트는 명확한 세분화의 렌즈를 통해 볼 때 가장 명확하게 나타납니다. 컴포넌트 차원에서는 컴퓨팅 장치 및 헤드 마운트 디스플레이와 같은 하드웨어 요소가 몰입형 경험의 근간을 이루고, 소프트웨어 솔루션은 중요한 시뮬레이션 컨텐츠, 성능 분석 및 절차 라이브러리를 제공합니다. 보완적으로, 관리형 서비스는 원활한 통합과 기술 지원을 보장하고, 전문 서비스는 커리큘럼 설계, 강사 교육, 기관의 요구에 대한 맞춤화를 촉진합니다.

북미, 유럽, 중동 및 아프리카, 아시아태평양의 VR 수술 훈련 채택에 관한 지역 역학 및 성장 요인 분석

지역적 역학은 VR 수술 교육 상황의 채택률, 투자 전략, 파트너십 모델에 큰 영향을 미칩니다. 미국 대륙에서는 탄탄한 헬스케어 인프라와 강력한 민간 투자, 지원적인 규제 프레임워크가 결합되어 몰입형 시뮬레이션 솔루션의 도입이 빠르게 진행되고 있습니다. 북미의 주요 학술 의료 센터와 확립된 외과 교육 프로그램은 시범 도입의 선구자이자 북미 대륙 전체에서 더 광범위한 수용을 위한 벤치마크를 설정하고 있습니다.

VR 수술 훈련 시장의 주요 혁신가들의 전략적 움직임과 경쟁 전략의 하이라이트

VR 수술 교육 분야의 주요 혁신가들은 기술 통합, 파트너 생태계, 컨텐츠 확장에 전략적으로 집중하여 경쟁력을 강화하고 있습니다. 몇몇 유명 하드웨어 제조업체들은 소프트웨어 개발자와의 전략적 제휴를 통해 최종사용자의 조달 및 배포 프로세스를 간소화하는 턴키 솔루션을 제공하기 위해 소프트웨어 개발자와의 전략적 제휴를 발표했습니다. 이러한 제휴는 헤드마운트 디스플레이, 컴퓨팅 유닛, 시뮬레이션 소프트웨어 간의 원활한 상호 운용성을 가능하게 하여 엔드투엔드 사용자 경험을 향상시킬 수 있습니다.

VR 수술 교육 발전의 새로운 기회와 과제를 해결하기 위한 전략적 권장 사항안 및 권장 행동 수립

VR을 활용한 수술 훈련의 새로운 기회를 활용하고 현재 진행 중인 과제를 극복하기 위해 업계 리더들은 다양한 시설의 요구와 예산에 맞는 모듈식 상호 운용 가능한 플랫폼 개발을 우선순위에 두어야 합니다. 하드웨어와 소프트웨어의 통합에 개방형 표준을 채택함으로써 솔루션 프로바이더는 애플리케이션 개발자와 액세서리 제조업체의 광범위한 생태계를 육성하고 교육 시나리오와 전문 모듈의 폭을 넓힐 수 있습니다.

데이터 수집 분석 및 시장 인사이트 정확도 검증을 지원하는 엄격한 다단계 조사 방법론에 대한 자세한 내용

이 시장 분석을 지원하는 조사 방법은 데이터의 완전성, 관련성 및 실용적인 인사이트를 보장하기 위해 설계된 엄격한 다단계 접근 방식을 따르고 있습니다. 먼저, 기술 동향, 연구개발, 경쟁사 포지셔닝에 대한 기초적인 이해를 높이기 위해 학술 간행물, 업계 백서, 규제 당국 신고, 기업 발표 등을 활용한 광범위한 2차 조사를 실시했습니다.

VR 수술 교육 및 훈련의 미래 궤적, 주요 연구 결과와 전략적 하이라이트의 통합을 통해 VR 수술 교육 및 훈련의 미래 궤적 파악

기술 발전, 규제 변화, 세분화 역학, 지역 추진력, 경쟁 전략을 종합적으로 분석하면 VR 수술 교육에 있으며, 매우 중요한 순간임을 알 수 있습니다. 몰입형 시뮬레이션 플랫폼은 고충실도 하드웨어, 적응형 소프트웨어, 증거 기반 검증 연구의 융합을 통해 시험적 도입에서 역량 기반 의학 교육의 핵심 구성 요소로 전환되고 있습니다.

목차

제1장 서문

제2장 조사 방법

제3장 개요

제4장 시장 개요

제5장 시장 역학

제6장 시장 인사이트

• Porter's Five Forces 분석
• PESTEL 분석

제7장 미국 관세의 누적 영향 2025

제8장 VR 수술 트레이닝 시장 : 컴포넌트별

• 하드웨어
  • 컴퓨팅 디바이스
  • 헤드 마운트 디스플레이(HMD)
• 서비스
  • 매니지드 서비스
  • 전문 서비스
• 소프트웨어

제9장 VR 수술 트레이닝 시장 : 기술별

• 전몰입형 VR
• 비몰입형 VR
• 반몰입형 VR

제10장 VR 수술 트레이닝 시장 : 트레이닝 모듈별

• 심장 수술
• 소화기 외과
• 신경외과
• 종양 외과
• 정형외과

제11장 VR 수술 트레이닝 시장 : 최종사용자별

• 학술·연구기관
• 병원·외과 연수 센터

제12장 아메리카의 VR 수술 트레이닝 시장

• 미국
• 캐나다
• 멕시코
• 브라질
• 아르헨티나

제13장 유럽, 중동 및 아프리카의 VR 수술 트레이닝 시장

• 영국
• 독일
• 프랑스
• 러시아
• 이탈리아
• 스페인
• 아랍에미리트
• 사우디아라비아
• 남아프리카공화국
• 덴마크
• 네덜란드
• 카타르
• 핀란드
• 스웨덴
• 나이지리아
• 이집트
• 튀르키예
• 이스라엘
• 노르웨이
• 폴란드
• 스위스

제14장 아시아태평양의 VR 수술 트레이닝 시장

• 중국
• 인도
• 일본
• 호주
• 한국
• 인도네시아
• 태국
• 필리핀
• 말레이시아
• 싱가포르
• 베트남
• 대만

제15장 경쟁 구도

• 시장 점유율 분석, 2024
• FPNV 포지셔닝 매트릭스, 2024
• 경쟁 분석
  • PrecisionOS Technology Inc.
  • Ghost Productions, Inc.
  • 3D Systems, Inc.
  • AutoVRse
  • Bioflight VR
  • BlockchainAppsDeveloper
  • CMR Surgical Ltd.
  • EnCata, Ltd
  • Fundamental Surgery
  • Health Scholars, Inc.
  • HQSoftware
  • ImmersiveTouch, Inc.
  • Infuse Media Group, LLC.
  • Interexy LLC
  • Johnson & Johnson Services, Inc
  • Mentice AB
  • Novac Technology Solutions
  • Osso VR
  • Proximie, Ltd.
  • SimX, Inc.
  • Surgical Science Sweden AB
  • Symgery
  • Vention
  • Verizon
  • VirtaMed
  • VRSim, Inc.

제16장 리서치 AI

제17장 리서치 통계

제18장 리서치 컨택

제19장 리서치 기사

제20장 부록

영문목차

The VR Surgery Training Market was valued at USD 345.27 million in 2024 and is projected to grow to USD 412.04 million in 2025, with a CAGR of 19.89%, reaching USD 1,025.46 million by 2030.

Understanding the Critical Role of Immersive Virtual Reality Platforms in Shaping the Next Generation of Surgical Training and Skill Development

Virtual reality technology is rapidly reshaping the landscape of surgical education by creating immersive, risk-free environments in which trainees can develop critical procedural skills. Medical institutions and training centers are increasingly integrating these platforms into curricula to bridge the divide between theoretical learning and hands-on practice. As the complexity of minimally invasive and robotic surgeries grows, so does the demand for simulation systems that offer high-fidelity feedback, repeatable scenarios, and data-driven performance metrics. This shift reflects a broader imperative within healthcare to enhance patient safety by ensuring that practitioners achieve proficiency before entering the operating room.

Moreover, the convergence of advanced graphics processing, haptic feedback devices, and cloud-based collaboration tools has elevated the effectiveness and scalability of virtual reality surgical modules. Educators now leverage rich anatomical modeling, procedural digitization, and real-time assessment dashboards to customize learning pathways that adapt to individual proficiency levels. With these developments, virtual reality platforms have transcended early proof-of-concept stages to become integral components of competency-based training frameworks. This introduction sets the stage for an in-depth exploration of the transformative shifts, regulatory impacts, segmentation insights, regional dynamics, and strategic imperatives that define the current and future state of virtual reality surgical training.

Identifying Pivotal Technological, Educational, and Regulatory Shifts Driving Transformation in Surgical Training Using Virtual Reality Innovations

Rapid technological advances, shifting educational paradigms, and evolving regulatory standards are collectively driving a fundamental transformation in how surgical training is conceived and delivered. The integration of machine learning algorithms with immersive simulation environments enables adaptive learning pathways that respond dynamically to a trainee's performance, thereby accelerating skill acquisition. Concurrently, medical schools and teaching hospitals are redesigning curricula to emphasize competency-based assessments over traditional time-based models, reflecting a broader transition toward outcomes-driven education.

At the same time, regulatory agencies and accreditation bodies have begun to recognize virtual reality simulation as a valid assessment tool for credentialing and certification. This validation has spurred increased investment in standardized training modules that align with procedural guidelines and competency benchmarks. Furthermore, the rise of tele-mentoring and collaborative simulation networks has expanded access to expert instruction across geographies, allowing trainees in remote or resource-constrained settings to participate in high-quality immersive learning experiences. Through these converging developments, the landscape of surgical education is being irrevocably shifted from passive observation and didactic learning to an interactive, metrics-enabled environment that prioritizes proficiency, reproducibility, and continuous improvement.

Evaluating the Comprehensive Implications of Newly Implemented 2025 United States Tariffs on Virtual Reality Surgical Training Ecosystems and Supply Chains

The imposition of new United States tariffs in 2025 has reverberated across the global supply chain for virtual reality hardware components and peripheral devices used in surgical training platforms. Manufacturers of head-mounted displays, computing units, and specialized haptic instruments have faced heightened import costs, prompting many to reassess their international procurement strategies. In response, several leading hardware developers have initiated regional manufacturing partnerships or shifted assembly lines to tariff-exempt jurisdictions in order to mitigate cost increases.

Concurrently, service providers that offer managed support and professional implementation services have had to adjust pricing models and contract structures to account for elevated equipment expenses. Training centers and academic institutions are negotiating bundled pricing agreements or exploring leasing arrangements to preserve budgetary flexibility. Despite these pressures, the market has seen accelerated collaborations between software vendors and hardware suppliers, focusing on integrated solutions that deliver value through streamlined deployment and reduced total cost of ownership. As a result, the tariff-driven realignment in sourcing and partnership models is fostering greater vertical integration, innovative financing mechanisms, and ultimately, a more resilient virtual reality surgical training ecosystem.

Deriving Actionable Insights from Core Market Segmentation Across Components, Technology, Training Modules, and End-User Profiles in VR-Enabled Surgical Education

Insight into market dynamics emerges most clearly when viewed through distinct segmentation lenses. Across the components dimension, hardware elements such as computing devices and head-mounted displays form the backbone of immersive experiences, while software solutions deliver critical simulation content, performance analytics, and procedural libraries. Complementarily, managed services ensure seamless integration and technical support, and professional services facilitate curriculum design, instructor training, and customization to institutional needs.

From a technology standpoint, fully immersive virtual reality platforms leverage advanced optics and haptic feedback to recreate surgical environments with high fidelity, while non-immersive systems rely on desktop or tablet interfaces for more accessible, cost-effective training modules. Semi-immersive configurations blend elements of both approaches, offering a middle ground that balances affordability with engaging user experiences. In terms of training modules, surgical disciplines such as cardiac surgery, gastroenterology, neurosurgery, oncology surgery, and orthopedic surgery each demand specialized anatomical models and procedural workflows to address unique educational objectives.

Finally, the end-user segmentation highlights the divergent requirements of academic and research institutions versus hospitals and surgical training centers. Academic settings emphasize structured curricula, research validation, and longitudinal competency tracking, whereas clinical training facilities often prioritize rapid deployment, procedural proficiency, and alignment with hospital credentialing pathways. By understanding these layered segmentations, stakeholders can align product development and go-to-market strategies with targeted user needs and institutional priorities.

Uncovering Regional Dynamics and Growth Drivers Across the Americas Europe Middle East and Africa and Asia-Pacific for Virtual Reality Surgical Training Adoption

Regional dynamics significantly influence adoption rates, investment strategies, and partnership models within the virtual reality surgical training landscape. In the Americas, robust healthcare infrastructure, combined with strong private-sector investment and supportive regulatory frameworks, has driven early uptake of immersive simulation solutions. Leading academic medical centers and established surgical training programs in North America have pioneered pilot implementations, setting benchmarks that guide broader acceptance across the continent.

Meanwhile, Europe, Middle East & Africa presents a heterogeneous environment characterized by divergent regulatory regimes and funding models. Western European nations benefit from centralized health systems and collaborative research consortia, facilitating multicenter validation studies and standardized curriculum modules. In contrast, Middle Eastern and African markets exhibit varying levels of infrastructure readiness, prompting solution providers to tailor packages that address power stability, network connectivity, and localized content requirements.

Across Asia-Pacific, rapidly expanding healthcare access, government initiatives to modernize medical education, and growing private investment in digital technologies are fueling demand for immersive training platforms. Key markets in the region are emphasizing public-private partnerships to bolster clinical skills development in underserved areas. As a result, solution providers are forging regional alliances and establishing local support centers to deliver cost-effective, scalable implementations. Recognizing these regional drivers and constraints enables market participants to fine-tune deployment strategies and maximize penetration.

Highlighting Strategic Movements and Competitive Strategies Employed by Leading Innovators in the Virtual Reality Surgical Training Market

Leading innovators in the virtual reality surgical training space are demonstrating a strategic focus on technology integration, partner ecosystems, and content expansion to strengthen their competitive positioning. Several prominent hardware manufacturers have announced strategic collaborations with software developers to deliver turnkey solutions that streamline procurement and deployment processes for end users. These alliances enable seamless interoperability between head-mounted displays, computing units, and simulation software, thereby enhancing the end-to-end user experience.

At the same time, software firms are securing partnerships with medical device companies and specialist procedure experts to enrich their simulation content libraries. By embedding accurate procedural workflows and real-time performance feedback, they are elevating the educational value proposition and supporting evidence-based training protocols. Meanwhile, service providers are expanding their portfolios through acquisitions of boutique professional training firms or by establishing dedicated centers of excellence to deliver on-site instructor certification and curriculum design services.

Furthermore, cross-sector collaborations with academic research institutions and surgical societies are enabling rigorous validation studies and the establishment of standardized competency benchmarks. This trend underscores a broader industry shift toward evidence-based validation of virtual reality modules to support accreditation and credentialing requirements. Collectively, these strategic movements highlight a maturing market in which innovation, alliance building, and quality assurance are key differentiators.

Formulating Strategic Imperatives and Recommended Actions to Navigate Emerging Opportunities and Challenges in Virtual Reality Surgical Training Advancement

To capitalize on emerging opportunities and navigate ongoing challenges in virtual reality-enabled surgical training, industry leaders should prioritize the development of modular, interoperable platforms that accommodate diverse institutional needs and budgets. By adopting open standards for hardware and software integration, solution providers can foster a broader ecosystem of application developers and accessory manufacturers, thereby expanding the range of training scenarios and specialized modules.

In parallel, forging strategic alliances with academic medical centers and professional societies will facilitate the creation of validated clinical content that aligns with evolving competency frameworks and accreditation criteria. These partnerships can also support longitudinal studies to quantify training efficacy, learner retention, and patient safety outcomes, providing robust evidence to inform purchasing decisions.

Furthermore, manufacturers and service providers should explore flexible financing and subscription models to reduce barriers to adoption in institutions with constrained capital budgets. Bundled offerings that combine equipment leasing, software licensing, and managed services can deliver predictable cost structures and simplify the acquisition process. Finally, investing in localized technical support, multilingual content, and infrastructure advisory services will be critical to scaling implementations across diverse regional markets. By executing on these strategic imperatives, industry leaders will position themselves to drive sustained growth and educational impact.

Detailing the Rigorous Multi-Stage Research Methodology Underpinning Data Collection Analysis and Validation for Market Insight Accuracy

The research methodology underpinning this market analysis follows a rigorous, multi-stage approach designed to ensure data integrity, relevance, and actionable insight. Initially, an extensive secondary research phase was conducted, drawing on academic publications, industry white papers, regulatory filings, and corporate announcements to establish a foundational understanding of technology trends, regulatory developments, and competitive positioning.

Subsequently, primary research interviews were carried out with a diverse set of stakeholders, including chief medical educators, surgical simulation specialists, technology developers, and procurement executives. These discussions yielded qualitative perspectives on adoption drivers, implementation challenges, and emerging use cases. Insights from these interviews were systematically synthesized and cross-referenced against secondary data points to validate key findings.

Data triangulation techniques were then applied to reconcile any discrepancies and to refine segmentation criteria based on real-world deployment scenarios and end-user feedback. Expert panels comprising leading surgeons, biomedical engineers, and academic researchers provided further validation of procedural models, learning outcome metrics, and performance evaluation frameworks. Throughout this process, stringent quality checks and peer reviews were implemented to ensure the reliability and robustness of the analysis.

Synthesizing Core Findings and Strategic Highlights to Illuminate the Future Trajectory of Virtual Reality-Enabled Surgical Training and Education

The collective analysis of technological advances, regulatory shifts, segmentation dynamics, regional drivers, and competitive strategies underscores a pivotal moment for virtual reality surgical training. Immersive simulation platforms are transitioning from pilot implementations to core components of competency-based medical education, driven by a convergence of high-fidelity hardware, adaptive software, and evidence-based validation studies.

While recent tariff adjustments have introduced cost pressures, they have concurrently catalyzed supply chain diversification, regional manufacturing partnerships, and creative financing solutions. Simultaneously, the maturation of segmentation approaches-across hardware, technology, training modules, and end-user categories-enables more targeted product development and go-to-market strategies. Regional insights highlight differentiated adoption models in the Americas, Europe Middle East & Africa, and Asia-Pacific, each presenting unique pathways for scale and localization.

Strategic collaborations among hardware manufacturers, software developers, academic institutions, and professional societies are fostering a robust ecosystem that prioritizes interoperability, content validation, and instructor competency. By embracing open standards, flexible financing structures, and localized support frameworks, stakeholders are well positioned to accelerate adoption and drive meaningful educational outcomes. This report's actionable recommendations provide a roadmap for navigating an evolving landscape where immersive training is set to redefine surgical proficiency and patient safety.

Table of Contents

1. Preface

• 1.1. Objectives of the Study
• 1.2. Market Segmentation & Coverage
• 1.3. Years Considered for the Study
• 1.4. Currency & Pricing
• 1.5. Language
• 1.6. Stakeholders

2. Research Methodology

• 2.1. Define: Research Objective
• 2.2. Determine: Research Design
• 2.3. Prepare: Research Instrument
• 2.4. Collect: Data Source
• 2.5. Analyze: Data Interpretation
• 2.6. Formulate: Data Verification
• 2.7. Publish: Research Report
• 2.8. Repeat: Report Update

3. Executive Summary

4. Market Overview

• 4.1. Introduction
• 4.2. Market Sizing & Forecasting

5. Market Dynamics

• 5.1. Integration of artificial intelligence analytics to provide personalized performance insights in VR surgery simulations
• 5.2. Emergence of subscription-based VR surgical training platforms with continuous content updates and assessments
• 5.3. Increasing adoption of haptic feedback systems to enhance realism in VR surgical training modules
• 5.4. Growing partnerships between academic medical centers and technology firms to standardize VR surgery training curriculums
• 5.5. Incorporation of real-time patient physiological data streams into virtual reality surgery practice scenarios
• 5.6. Development of ultra-high-fidelity anatomical models using photogrammetry and 3D scanning in VR training environments
• 5.7. Expansion of cloud-based collaborative virtual operating rooms for remote surgical training sessions
• 5.8. Expansion of cost effective standalone VR headsets facilitating scalable surgical skills training programs
• 5.9. Adoption of advanced motion tracking sensors to enhance precision and spatial awareness in virtual surgical practice
• 5.10. Implementation of data analytics and performance metrics dashboards for continuous improvement in VR surgery education

6. Market Insights

• 6.1. Porter's Five Forces Analysis
• 6.2. PESTLE Analysis

7. Cumulative Impact of United States Tariffs 2025

8. VR Surgery Training Market, by Components

• 8.1. Introduction
• 8.2. Hardware
  • 8.2.1. Computing Devices
  • 8.2.2. Head-Mounted Displays
• 8.3. Services
  • 8.3.1. Managed Services
  • 8.3.2. Professional Services
• 8.4. Software

9. VR Surgery Training Market, by Technology

• 9.1. Introduction
• 9.2. Fully Immersive VR
• 9.3. Non-Immersive VR
• 9.4. Semi-Immersive VR

10. VR Surgery Training Market, by Training Module

• 10.1. Introduction
• 10.2. Cardiac Surgery
• 10.3. Gastroenterology
• 10.4. Neurosurgery
• 10.5. Oncology Surgery
• 10.6. Orthopedic Surgery

11. VR Surgery Training Market, by End-User

• 11.1. Introduction
• 11.2. Academic & Research Institutions
• 11.3. Hospitals & Surgical Training Centers

12. Americas VR Surgery Training Market

• 12.1. Introduction
• 12.2. United States
• 12.3. Canada
• 12.4. Mexico
• 12.5. Brazil
• 12.6. Argentina

13. Europe, Middle East & Africa VR Surgery Training Market

• 13.1. Introduction
• 13.2. United Kingdom
• 13.3. Germany
• 13.4. France
• 13.5. Russia
• 13.6. Italy
• 13.7. Spain
• 13.8. United Arab Emirates
• 13.9. Saudi Arabia
• 13.10. South Africa
• 13.11. Denmark
• 13.12. Netherlands
• 13.13. Qatar
• 13.14. Finland
• 13.15. Sweden
• 13.16. Nigeria
• 13.17. Egypt
• 13.18. Turkey
• 13.19. Israel
• 13.20. Norway
• 13.21. Poland
• 13.22. Switzerland

14. Asia-Pacific VR Surgery Training Market

• 14.1. Introduction
• 14.2. China
• 14.3. India
• 14.4. Japan
• 14.5. Australia
• 14.6. South Korea
• 14.7. Indonesia
• 14.8. Thailand
• 14.9. Philippines
• 14.10. Malaysia
• 14.11. Singapore
• 14.12. Vietnam
• 14.13. Taiwan

15. Competitive Landscape

• 15.1. Market Share Analysis, 2024
• 15.2. FPNV Positioning Matrix, 2024
• 15.3. Competitive Analysis
  • 15.3.1. PrecisionOS Technology Inc.
  • 15.3.2. Ghost Productions, Inc.
  • 15.3.3. 3D Systems, Inc.
  • 15.3.4. AutoVRse
  • 15.3.5. Bioflight VR
  • 15.3.6. BlockchainAppsDeveloper
  • 15.3.7. CMR Surgical Ltd.
  • 15.3.8. EnCata, Ltd
  • 15.3.9. Fundamental Surgery
  • 15.3.10. Health Scholars, Inc.
  • 15.3.11. HQSoftware
  • 15.3.12. ImmersiveTouch, Inc.
  • 15.3.13. Infuse Media Group, LLC.
  • 15.3.14. Interexy LLC
  • 15.3.15. Johnson & Johnson Services, Inc
  • 15.3.16. Mentice AB
  • 15.3.17. Novac Technology Solutions
  • 15.3.18. Osso VR
  • 15.3.19. Proximie, Ltd.
  • 15.3.20. SimX, Inc.
  • 15.3.21. Surgical Science Sweden AB
  • 15.3.22. Symgery
  • 15.3.23. Vention
  • 15.3.24. Verizon
  • 15.3.25. VirtaMed
  • 15.3.26. VRSim, Inc.

16. ResearchAI

17. ResearchStatistics

18. ResearchContacts

19. ResearchArticles

20. Appendix