India Augmented Reality in Healthcare Market 2026 – 2035

Reports Description

The market size of augmented reality in healthcare in India is estimated at USD 87.50 million in 2025 and is estimated to rise to between USD 105.78 million in 2026 and about USD 621.45 million in 2035 with a CAGR of 20.92% between 2026 and 2035.

The market is growing due to the rising prevalence of non-communicable diseases and chronic diseases, the rapid development of the healthcare infrastructure, the rise in medical education and training needs, the positive governmental digital health policies, the increase in healthcare spending, the development of AR technologies, and the trend towards the high usage of innovative healthcare services.

Market Highlight

• India has a market share of about 8.5% of the Asia-Pacific market share of augmented reality in healthcare in 2025, which is one of the most rapidly developing market shares in the region.

• By component, the hardware segment was estimated to have the largest market share of approximately 58% in 2025 as more people continue to buy AR headsets, smart glasses, and head-mounted displays.

• By component, the software segment has the highest CAGR of 22.15% between 2026 and 2035, which has been propelled by AR applications, AI integration, and cloud based platforms.

• Application wise, the medical training and education segment had the largest market share of 34% in 2025 with the surgical planning and navigation segment projected to have a CAGR of 23.47% within the forecast period of 2026 to 2035.

• By end user, hospitals and clinics will have the largest share of the market in 2025 with 52% of the share, with pharmaceutical companies increasing at the highest rate of 22.84% CAGR.

• By 2025, there are an estimated 2,000 startups in India that deal with AR and VR technology, which has established a strong ecosystem of innovators that drive further progress in the medical application of these technologies.

Significant Growth Factors

The India Augmented Reality in Healthcare Market Trends presents significant growth opportunities due to several factors:

• Escalating Burden of Non-Communicable Diseases and Healthcare Transformation: The fast rising rates of non-communicable diseases (NCDs) and other chronic diseases are the first driver to adopt AR in healthcare since millions of Indians need advanced diagnostic, treatment, and monitoring technologies, which AR solutions offer in order to achieve better clinical outcomes and patient engagement. In terms of the disease burden, non-communicable diseases and injuries combined in 2016, the NCDs caused 61.8% of all deaths, increasing the figure from 37.9% in 1990, and the India State-Level Disease Burden Initiative shows that the epidemiological transition has been dramatic, necessitating innovative healthcare technologies in India. In India, cardiovascular diseases, cancers, chronic respiratory diseases, and diabetes are the four major illnesses that are attributable to NCDs that make up an estimated 56.5% of the total disease burden in the year 2025, developing insurmountable pressures on AR-driven diagnostic imaging, surgical planning, and patient monitoring solutions. Heart disease is one of the leading causes of mortality, with cardiovascular disease taking up about 27% of all deaths in India in 2016 with heart disease coming in second at 11%, cancer at 9%, and diabetes at 3%, indicating a significant need to develop advanced visualization that is capable of improving clinical decision-making in these areas of therapy. It is estimated that 28% of elderly people in India are affected by various diseases and that 63% of all mortality can be traced to chronic illnesses, which points to the complexity of healthcare service provision necessitating complex AR tools to manage patients and coordinate their treatment and track their progression. The geriatric care trend, rehabilitation, and management of age-related diseases represent a long-term demand on AR applications to help meet the healthcare needs of the aging population, who will experience significant demand, with the number of elderly people projected to increase to 158.7 million in 2025 (11.1% of the total population) and to 340 million by 2050. The prevalence of diabetes has been soaring up and the incidence has risen to 264.53 per 100,000 compared to 162.74 per 100,000 between 1990 and 2021, and it is expected to rise to 8585.45 per 100,000 by 2031, which has led to the adoption of AR-enabled patient education, treatment monitoring, and self-management tools that are expected to improve the treatment outcomes in diabetes care. Air pollution rates in India are the highest in the world, and they caused 10% of the total disease burden in 2016, and the ambient air pollution burden has been growing in all regions of India since 1990, and thus AR-based diagnostic arts of respiratory diseases and air pollution of the environment are required. Unhealthy diets, physical inactivity, and urbanization have made it easy to develop lifestyle disorders such as obesity, hypertension, and metabolic syndrome, and this presents a niche where AR applications can be used in preventive healthcare, wellness management, and the promotion of healthy lifestyles and disease prevention.

• Rapid Healthcare Infrastructure Expansion and Government Digital Health Initiatives: Government support of digital healthcare development, healthcare infrastructure development, and technology adoption are the key drivers of growth, and the significant investment in building hospitals, medical education, and digital healthcare platforms has created a comfortable environment to implement AR technology into the healthcare ecosystem in India. The total health expenditure of India amounted to 3.8 of total health expenditure, 9.04 lakh crore in financial year 2022 at current prices (equivalent to 6602), increasing from 29.0 to 48.0 of a total health expenditure between FY15 and FY22 indicating a significant deposit of the government in developing India into a modernized healthcare sector in the support of AR adoption. Health spending went up sharply to Rs 6.1 lakh crore in 2024-2025 compared to 3.2 lakh crore in 2020-2021, which is a compound annual growth rate of 18%, and the level of capital spending has increased to 12.7% in 2022 compared to 6.3% in 2016, which is a sign of substantial infrastructure investments that are generating avenues to integrate advanced technology such as AR systems. The Union Budget 2025-26 has set up spending on healthcare at 99,858.56 crore, an increase of 11% over spending on healthcare in 2024-25 (89,974 crore), and Ayushman Bharat PMJAY (9,406 crore of expenditure) and PM Ayushman Bharat Health Infrastructure Mission (4,200 crore of expenditure) will facilitate the modernization of facilities and the adoption of new technologies in healthcare. Ayushman bharat is a healthcare facilities universalization initiative started in 2017-18, which has already enrolled more than 4 million elderly citizens as of January 2025, resulting in the creation of massive healthcare usage that fosters the demand for high-tech innovations such as AR systems that enhance the effectiveness and quality of care provided by clinics. According to Invest India, USD 370 billion was invested in the health sector in 2022, which attests to massive capital inflows in healthcare infrastructure, medical technology, and digital health platforms to generate a market opportunity among the providers of AR solutions in hospitals, diagnostic centers, and medical institutions. Amrita Hospital expanded its reality ecosystem in June 2023, using AR, VR, and mixed reality technologies to expand its capabilities significantly in all areas of work with patients, medical training, and research, becoming a big step in the digital sector of the healthcare industry in India and showing that the institution is committed to using immersive technologies. In July 2024, the Government of Karnataka and Meta introduced the Digi Nagrik Program to train 100000 teachers and 1 million students on digital safety and AR-VR by 2025, showing that the government is supportive of immersive technology education to produce skilled workers to assist the adoption of AR healthcare. Ayushman Bharat Digital Mission (ABDM) is supposed to establish a common digital health infrastructure comprising of electronic health records, telemedicine services, and digital health, along with the ability to integrate AR technology with the existing healthcare information systems and provide interoperability to support comprehensive AR healthcare solutions.

What are the Major Advances Changing the India Augmented Reality in Healthcare Market Today

• Artificial Intelligence Integration and Advanced AR Software Solutions: The most significant change in the field of healthcare AR systems is the combination of artificial intelligence and augmented reality, which will allow recognizing images intelligently, assist in diagnosing, predicting analytics, and personalized treatment recommendations that can contribute greatly to clinical decision-making, increase diagnostic accuracy, and increase efficiency in the delivery of care to patients. The Economic Survey 2024-25 estimates that 34% of Indian healthcare organizations were piloting AI projects in 2023 and 16% had transitioned generative AI projects into production, indicating that organizations have a high organizational preparedness for AI-AR convergence by developing complex healthcare solutions through visual augmentation in conjunction with intelligent data analysis. The AI in the form of the AR app can be used for real-time identification of anatomical structures during surgical interventions, identification of pathological changes in medical imaging, predictive surgical navigation, and individual patient visualization through specific anatomical variations, enhancing surgical accuracy and minimizing complications during the procedure. Machine learning systems used with AR systems process patient data based on electronic health records, diagnostic images, and clinical parameters to produce augmented visual overlays of risk factors, treatment choices and prognostic indicators to support evidence-based clinical decision-making at the point of care. NLP with AR technology can be used for voice-controlled interfaces, autoclinical documentation, and smart information searches during surgery operations to enable surgeons to read vital information and manipulate AR displays without the use of their hands, enhancing operational efficiency and ensuring a sterile field. Remote expert consultation, distributed medical training, telesurgery guidance, and collaborative treatment planning Cloud-based AR systems with AI can augment specialists expertise to underserved regions and assist with complex clinical cases that need multidisciplinary involvement no matter the geographical location. The software category with the highest growth rate, 22.15% CAGR indicates the sophistication of AR applications, as developers have developed specialized applications in particular clinical specialties, are integrating with hospital information systems, and are incorporating AI algorithms that provide more sophisticated functionality than the simple AR visualization solutions.

• Surgical Planning, Navigation, and Intraoperative AR Applications: Surgical-planning AR and intraoperative-navigation solutions constitute a radical innovation in the surgical process and will allow surgeons to visualize patient anatomy, plan surgery, guide complex procedures with augmented guidance, and improve surgical outcomes due to increased patient spatial awareness and procedural accuracy. The fastest growing segment of surgical planning and navigation is with the highest CAGR of 23.47, which indicates the strong value proposition of AR in surgical specialties, and orthopedics, neurosurgery, cardiovascular surgery, and oncological surgery are the specialties that have started using AR technologies to enhance the accuracy of the procedures and patient safety. AR surgical navigation systems superimpose the preoperative anatomy (CT, MRI, ultrasound) over the anatomy of a patient in real-time during a surgical operation, giving the surgeon the ability to see through tissues and visualize underlying anatomy, tumors, blood vessels, and other important anatomical structures to deliver the perfect surgical operation with minimal collateral damage. In 2024, KIMS Hospital in India applied AR and AI in neurosurgery and reduced complexities and human errors, showing that AR surgical navigation is practical in complex brain surgery with a millimeter-accurate precision requirement, and AR guidance can allow the surgeon to avoid important structures whilst optimizing surgical corridors. In 2025, the LungVision advanced imaging system of Body Vision Medical was given regulatory approval through the Therapeutic Goods Administration of India and was a sign of regulatory validation of AI-powered AR intraoperative imaging as an expanding field of use beyond traditional surgical specialties into thoracic surgery. AR-based minimally invasive surgery offers better visualization of laparoscopic and robotic surgeries, superimposing anatomic structures, surgical margins, and instrument processes on endoscopic video images, which minimally invasive techniques lack in direct visualization. Applied to medical imaging, three-dimensional AR reconstruction of patient anatomy facilitates preoperative surgical rehearsal during which surgeons can train complicated surgeries, discover possible complications, refine surgical plans and strategies, and draft contingency plans prior to entering the operating room to enhance surgical preparedness and confidence. Doppler imaging, CT angiography (vascular anatomy), and PET scans (tumor margins) of blood flow give surgeons multimodal information synthesis on intraoperative decision-making on oncological resections, vascular procedures, and organ transplantation surgical procedures using augmented reality visualization of blood flow. AR-based Remote surgery guidance allows the work of qualified surgeons in real-time mentorship on complicated operations, overlaying annotations, surgical guidelines, and anatomical directions identifiable to operating surgeons on AR screens, allowing skills transfer and outcome enhancement in facilities with evolving surgical experience.

• Medical Training, Education, and Immersive Learning Platforms: The implementation of AR in medical training and education is a paradigm shift in medical professional development, with non-cadaver based anatomy training and apprenticeship learning being replaced with immersive, repeatable, and risk-free training simulations that accelerate skill acquisition, knowledge retention, and medical specialty clinical competency. Medical training and education segment with the greatest market share of 34% in 2025 will represent the transformative effect of AR on medical education, with medical schools, nursing colleges, and allied health programs, along with continuing medical education providers, integrating AR to add to their standard teaching and learning with interactive 3D image visualization and hands-on simulation. AR anatomy education systems offer learners interactive 3D anatomical models superimposed on the physical environment or projection surface, allowing learners to experience anatomy in a variety of positions, visualize the internal organs, learn more about the anatomy connections, and train their identification skills without using cadavers or anatomy models. AR technology is applied to surgical simulation, which lets medical residents and surgical trainees practice surgical procedures in a simulated setting, which helps them to develop psychomotor skills, learn surgical processes, be exposed to procedural complications, and have performance feedback before they can perform surgery on real patients, which shortens the learning curve and improves patient safety. The example of the Government of Karnataka and Meta’s Digital Nagrik Program, or training 100,000 teachers and 1 million students on the skills of AR-VR indicates the development of expected infrastructure to support the use of AR in the educational program, generating the generation or training of medical workers who have a clear understanding of the application of AR in their work and would be ready to use AR tools in their practice. AR-based training on patient examination can allow medical students to train on physical examination skills, diagnosis, and skills in interaction with patients by using virtual patients with different clinical presentations, pathology, and diseases, and these standards give them a consistent training experience, which guarantees competency building. AR-integrated clinical skills laboratories can be used to help nursing and allied health students to practice such procedures as venipuncture, catheterization, medication intake, and even patient care methods on virtualized patients or real mannequins where AR overlays are used to provide real-time feedback and evaluation. Continuing medical education programs based on AR platforms help practicing physicians to refresh their clinical knowledge, acquire new surgical skills, learn new technologies, and ensure board certification through immersive learning technologies through which remote courses do not require traveling and scheduling issues prevent involvement in CME programs. The pharmaceutical industry is currently implementing AR to train its medical representatives and allow sales staff to learn about drug mechanisms and disease pathophysiology, practice physician interaction, and illustrate product benefits in an immersive environment to enhance knowledge storage and communication with healthcare professionals.

Category Wise Insights

By Component

Why Hardware Leads the Market?

Hardware is the biggest segment that will go up to about 58% of the total market share in 2025. Such dominance is based on the core need in AR-enabled devices capable of healthcare use, where the healthcare facilities, medical schools, and medical practitioners have invested in the head-mounted displays, smart glasses, and handheld AR devices as the backbone infrastructure to the AR software implementation. The hardware prevails through the high initial capital investment of purchasing AR devices (the cost of purchasing a head-mounted display and smart glasses is USD 3,000-10,000 per unit and USD 1,500-5,000 per unit, respectively) and generates substantial hardware-related revenues as opposed to software subscription models, which usually cost USD 500-2,000 per user per year. HMDs such as Microsoft HoloLens and Magic Leap will provide high-resolution screens, advanced spatial mapping, gesture sensing, and processing power, which will be important in complex surgical navigation and medical education challenges and command a high price due to their extensive functionality. Healthcare-specific smart glasses offer lightweight and comfortable designs that can be worn during long surgical procedures, and enterprise-oriented products of Vuzex, Epson, and RealWear have hands-free functionality, voice input and support, and an interface with hospital information systems to enable medical operations to run efficiently. The entry points of healthcare organizations, particularly tablets and smartphones with AR applications, are accessible and less expensive, with user-friendly interfaces, compatibility with existing institutional devices, and the ability to support a quick adoption of AR in patient education, rehabilitation therapy, and the basic training of medical personnel in applications of AR. This growth in hardware segments is supported by the growing number of AR-enabled devices in Indian healthcare amenities as infrastructure modernization programs and technology investments enabled by government expenditures on healthcare grow, and various institutions set up AR facilities and infrastructure to handle a wide range of applications in the surgical, education, and patient care segments.

Software is also in the highest growth with a projected CAGR of 22.15% in the period between 2026 and 2035 due to the accelerated innovation of AR applications, the sophistication of AR software solutions, the integration of AI to enhance functionality, and the recurring revenue model through subscriptions that generates long-term growth opportunities for software developers and healthcare technology companies. AR software apps meet individual clinical requirements in areas of surgical navigation, medical education, patient care, and diagnostic imaging, with focused solutions designed to meet the needs of a specific medical specialty providing specific functionality, integration with clinical workflows, and evidence-based validation to demonstrate clinical value and return on investment. The implementation of artificial intelligence, machine learning, computer vision, and natural language processing into AR software platforms develops intelligent applications with automated image analysis, predictive guidance, personalized recommendations, and adaptive learning functions that greatly increase the clinical utility of AR visualization in comparison to the fundamental AR visualization. Remote access, collaborative applications, centralized content management, automatic updates, and scalability are made possible by cloud-based AR systems to serve the needs of multi-site healthcare organizations, telemedicine applications, and distributed medical education programs without having to invest in on-premise infrastructure. Third-party developers, healthcare institutions, and medical device companies can build specific AR applications to meet the needs of particular institutions, clinical processes, and specialty services and promote the rich AR healthcare software ecosystem through the proliferation of AR development platforms, software development kits, and application programming interfaces.

By Application

Why Medical Training and Education Dominate AR Applications?

The greatest segment is medical training and education applications which will take about 34% of overall market share in 2025. Such leadership indicates that AR has a transformational effect on medical education and technology provides immersive, interactive, and repeatable learning experiences that are more compelling than conventional education delivery models, which forms a great value proposition for medical schools, nursing colleges, and continuing education providers. The high healthcare workforce deficits in India, where there are large numbers of physicians to patients and nurse to patient ratios that are far below national and international recommended proportions, would signal a dire need of an efficient training solution that AR would provide by increasing the expediency in skills acquisition, standardizing education, and further provide expert training to underserved regions through technology scaled platforms. Education in medical anatomy is one of the main areas of application, as AR platforms allow students to visualize anatomy and complex internal organs, learn the spatial relationships, and practice anatomical identification by providing interactivity that is better than conventional textbooks, anatomical models, and cadaver dissection as a primary source of foundational knowledge building. AR technology in surgical simulation gives residents a safe space to practice and build psychomotor skills, simulate complications and get performance feedback without risk to patients, and outperform ethical issues of learning on patients as well as shorten surgical learning curves. The solution of 100,000 teachers and 1 million students being prepared with AR-VR skills in the Government of Karnataka Digital Nagrik Program is an example of developing an educational ecosystem that accommodates AR integration into the academic curriculum and a standardized base of digital skills that allows the wholesale adoption of AR by educational institutions. Ar-based clinical skills training allows introducing nursing and allied health students to patient examination, diagnostic, venipuncture, medication administration, and emergency response procedures on simulated patients, offering realistic clinical scenarios and standardized presentations to ensure competency evaluation. Ongoing medical training based on AR platforms allows practicing doctors to uphold clinical knowledge, acquire new skills, and fulfill the certification requirements using the option of remote education that has no geographic limitations and allows arranging the education time with no scheduling conflicts, unlike the traditional CME conferences and workshops.

Surgical planning and navigating is the category with the highest growth rate of 23.47% between 2026 and 2035 due to the persuasive clinical value proposition whereby AR direction has resulted in better surgical accuracy, fewer complications, extended procedures, and less invasive operations, which has led to a strong payback of an investment to warrant the use of technology by a hospital or surgical facility. AR visualization is of significant value to the complicated anatomy in neurosurgery, orthopedic surgery, cardiovascular surgery, and oncological surgery fields, allowing intraoperative guidance to enable the surgeon to navigate vital organs, critical structures, optimal tumor resection margins, and optimal approaches to the surgery, which translate to better patient outcomes and less revision surgery. The adoption of AR and AI in neurosurgery at KIMS Hospital in April 2024 is a practical clinical indication of AR adoption in India, with institutions acknowledging that AR can simplify the complexity of surgery, decrease human errors, and improve the outcome in high stakes procedures where millimeter accuracy is required which is evidence of the business case to invest in AR.

By End User

Why Hospitals and Clinics Dominate the Market?

The biggest segment is the hospitals and clinics, which will have about 52% market share in 2025. This is a manifestation of the dominance of the hospitals as the primary healthcare delivery environments in which AR applications provide immediate clinical utility by providing surgical navigation, enhanced diagnostic imaging, patient care management, and emergency medicine applications, generating strong use cases that warrant significant technology spending. Large corporate hospitals and multi-specialty medical centers have financial bases, technical infrastructure, and clinical volumes that support adoption of AR technology, capital budgets to buy equipment; IT departments to implement the procedure; and a volume of procedures to pay back the investment in terms of better surgical outcomes, fewer complications, and efficient operations. The fact that Amrita Hospital had already adopted a complete AR, VR, and mixed reality ecosystem in June 2023 indicates the institutional belief in immersive technologies, and top healthcare institutions are now able to realize competitive advantages due to the adoption of technology, including improved reputation, patient attraction, physician recruitment, and clinical research facilities facilitated by advanced AR infrastructure. Surgical departments are considered to be the major adoption sites in hospitals, and orthopedic surgery, neurosurgery, cardiovascular surgery, and general surgery departments are the ones that have adopted AR navigation systems, surgical planning systems, and intraoperative guidance technologies, which enhance the precision of the procedures, decrease the operating time, and result in safer practice, generating a quantifiable clinical and financial outcome. AR is used in emergency departments for challenging venous access, traumatic evaluation with AR-improved picture examination, and telemedicine meetings with specialists through AR to emphasize pathological findings to enhance emergency care provision and clinical judgment in urgent cases. AR is incorporated in diagnostic imaging departments to improve image interpretation; radiologists can potentially visualize complex three-dimensional anatomy and detect subtle changes in patients and share findings with referring physicians using AR enhanced images that better depict the disease extent and anatomical relationships in relation to the traditional 2D displays.

Pharmaceutical firms are on the strongest path with an expected CAGR of 22.84 between the years 2026 and 2035 as a result of the growing use of AR in clinical trial recruitment and management, drug mechanism visualization in healthcare provider education, patient support management in improving adherence, and medical representative training in emerging sales efficiency. Pharmaceutical firms are using AR to visualize drug mechanisms of action at the molecular, cellular, and organ system level to produce an attractive educational experience for physicians, showing how drugs interact with biological targets, generate therapeutic effects, and differ from other products to improve prescriber knowledge and evidence-based prescribing. AR-based clinical trials have been associated with better patient recruitment by providing education content about the study procedures, better protocol adherence via AR-monitored medication administration and symptom reporting, and remote trial execution via AR telemedicine technology and its capacity to minimize site visit activities and expand geographically. Pharmaceutical-driven patient support programs use AR to deliver medication administration, disease education, treatment monitoring, and adherence support, which result in better patient outcomes and medication treatment adherence, which create value to patients, payers, and pharmaceutical companies in the case of chronic disease medications that require long-term treatment. Training of medical representatives with the help of AR allows pharmaceutical sales forces to learn complex disease pathophysiology, visualize the effect of drugs, practice communication with a physician, and display product benefits through immersion to enhance knowledge retention, effective communication of salaries, and sales for the sales team to achieve the goal of market access and revenue growth.

Report Scope

Top Players in the Market

• Microsoft Corporation
• Google LLC
• Augmedics
• AccuVein Inc.
• EchoPixel Inc.
• Medivis Inc.
• Infosys Limited
• Tata Consultancy Services (TCS)
• Wipro Limited
• HCL Technologies
• Others

Key Developments

The market has undergone significant developments as industry participants seek to expand capabilities and enhance product offerings.

• In July 2024: The Government of Karnataka and Meta have started the program of Digital Nagrik. It aims to provide 100,000 teachers and 1M students with digital safety and AR/VR skills by 2025. This depicts how the public sector is very dedicated to teaching immersive technology to produce a skilled workforce that will stop the adoption of AR healthcare in India.

• In June 2023: Amrita Hospital enlarged its reality world with the help of AR, VR, and mixed reality. All these tools are very good in enhancing patient care, medical training, and research. It is a significant breakthrough in the history of the Indian digital health sector and a sign of the commitment of leading institutions to the full adoption of immersive technology.

These strategic activities have allowed companies to strengthen market positions, expand technological capabilities, enhance clinical applications, and capitalize on growth opportunities within the rapidly expanding market.

The India Augmented Reality in Healthcare Market is segmented as follows:

By Component

• Hardware
  • Head-Mounted Displays
  • Handheld Devices
  • Smart Glasses
• Software
  • AR Applications
  • AR Development Platforms
  • Cloud-Based Solutions

By Application

• Surgical Planning and Navigation
• Medical Training and Education
• Patient Care Management
• Rehabilitation and Therapy
• Diagnostic Imaging
• Other Applications

By End User

• Hospitals and Clinics
• Medical Training Institutions
• Pharmaceutical Companies
• Other End Users