Medical Radiation Detection Assessment, By Detector Type [Gas-Filled Detectors, Scintillators, Solid-State Detectors], By Product Type [Personal Dosimeters, Area Process Dosimeters, Surface Contamination Monitors, Others], By End-user [Hospitals, Radiolog

Medical Radiation Detection Assessment, By Detector Type [Gas-Filled Detectors, Scintillators, Solid-State Detectors], By Product Type [Personal Dosimeters, Area Process Dosimeters, Surface Contamination Monitors, Others], By End-user [Hospitals, Radiology Centers, Ambulatory Surgery Centers, Clinics, Others], By Region, Opportunities and Forecast, 2017-2031F



Global medical radiation detection market is projected to witness a CAGR of 7.04% during the forecast period 2024-2031F, growing from USD 1.13 billion in 2023 to USD 1.95 billion in 2031F. The market has experienced significant growth in recent years and is expected to maintain a strong pace of expansion in the coming years.

Medical radiation detection is necessary for using tools and devices to ensure the safety of everyone around it. Hazardous radiation is identified and lessened by the devices used for medical radiation safety, monitoring, and detection. To provide safe radiological circumstances in places of employment, such as imaging centers and hospitals, medical radiation detection, and monitoring is devised to keep a check on radiation levels in the environment as well as its exposure to the working professional.

All around the world, governments have put laws and regulations in place to control the use of medical radiation as they understand the possible risks involved. To help reduce radiation exposure from medical imaging, the Food and Drug Administration (FDA) in the United States, for instance, has released guidelines to healthcare professionals. The FDA advises against doing needless imaging exams and to use the lowest radiation dose required to produce a diagnostic-quality image. Another initiative to promote the appropriate use of advanced diagnostic imaging services has been put in place by the Centres for Medicare and Medicaid Services (CMS). The necessity for medical radiation detection equipment has expanded along with the need for medical imaging.Medical Tourism is becoming very popular and is now widely accepted. The government has contributed to it in the form of heavy investments and infrastructure. Research and development have strongly supported the best and most advanced technology, which detects the radiation doses and prevents from getting more than the required radiation to its users and the healthcare technicians.

For instance, in 2022, Infab, LLC (USA) introduced its innovative product, the 903 Reverse Vest & Skirt, designed to offer robust protection against scatter radiation while ensuring a secure and comfortable fit for users. It has a wide range of products in different designs and models and offers a high-level protection against radiation.

Rising Incidence of Cancer to Boost the Market

Radiation therapy is an essential part of cancer treatment and cancer is one of the main causes of deaths globally. Radiation therapy is getting more in demand due to the number of cancer patients. For instance, according to data published by a journal of American Cancer Society in 2024, 2,001,140 new cancer cases and 611,720 cancer deaths are projected to occur in the United States. To guarantee that patients receive the appropriate dosage of radiation during treatment, the necessity for precise and efficient radiation detection systems comes into light. Imaging methods that use ionizing radiation, such as CT, PET, and X-rays, are frequently used in the diagnosis of cancer. As the number of cancer cases rises, the need for diagnostic imaging increases the need for radiation detection equipment to protect patients during these treatments.

Precision medicine and individualized treatment regimens are the direction of advancements in cancer care. Radiation therapy is getting increasingly patient-specific and focused. To precisely assess and manage the radiation dose delivered to tumors while minimizing damage to healthy tissues, precision necessitates the use of sophisticated radiation detection devices. To ensure that patients receive the appropriate therapy with the fewest possible side effects, healthcare facilities and practitioners are investing in radiation detection equipment to monitor and verify radiation doses. Radiation safety regulations are being enforced by regulatory bodies in a more rigorous manner. These standards, which require the use of trustworthy radiation detection equipment, must be followed by healthcare establishments. Penalties, legal repercussions, and reputational harm to a facility are possible outcomes of non-compliance, which increases demand for compliant solutions.

Increasing R&D Investments to Fuel the Market

The development of radiation detection technologies is fueled by research and development expenditures. It includes the creation of detectors that are more sensitive, sophisticated algorithms for data processing, and system integration with other healthcare systems. Healthcare providers seeking to enhance patient safety and diagnostic or therapeutic precision are drawn towards innovative solutions, hence propelling the market expansion. Investments in R&D result in the development of radiation detection tools with enhanced performance metrics. It entails improved dependability, decreased detection limits, and enhanced dose measurement accuracy.

The market demand is increasing as healthcare facilities look for these devices to maximize radiation therapy and diagnostic processes. The systems' flexibility to accommodate diverse medical domains such as cardiology, radiology, or oncology eventually increases their attractiveness to healthcare providers. The advancement of real-time monitoring capabilities is facilitated by ongoing R&D investments. It improves patient safety by enabling healthcare providers to monitor radiation exposure in real-time during procedures and make quick modifications as needed. Such real-time monitoring systems are in high demand, which drives market expansion. It is becoming more crucial to integrate radiation detection data with electronic health records. By facilitating data-driven decision-making and quality enhancement, integration promotes market growth. Investments in R&D produce advances which allow radiation doses to be lowered while preserving therapeutic and diagnostic efficacy. It is especially important for radiation therapy and medical imaging since it follows the ALARA (As Low as Reasonably Achievable) philosophy.

Radiation detection systems' primary selling point, which propels their adoption, is reduced radiation exposure. Integration of AI and radiology is a blessing to the healthcare industry.Heavy research and development across the globe are going on to produce the best results. It presents a great opportunity for the market to expand. For instance, recently in February 2024, Kormek Group was awarded EUR 1.3 million to participate in the Intelligent Radiation Sensor Readout System (i-RASE) project for developing a new class of radiation sensor powered by artificial intelligence (AI).

Dominance of Personal Dosimeters Segment

The sector of personal dosimeters holds a notable market share owing to its vital function in ensuring the safety of radiation professionals and healthcare personnel. People who are exposed to ionizing radiation use personal dosimeters, which allow them to monitor their radiation exposure levels in real time. The need for personal dosimeters has increased due to rising radiation safety awareness, strict regulatory requirements, and an increase in the number of radiation-related diagnostic and therapeutic procedures. The industry's dedication to maintaining worker safety and adhering to radiation protection regulations is seen in the segment's significance, which in turn contributes to its sizeable market share. When workers are in locations where radiation exposure poses a risk, personal dosimeters are used to track their radiation exposure levels. It is especially crucial for ionizing radiation-exposed businesses such as radiography, nuclear power, and medical imaging. By preventing workers from being exposed to hazardous radiation levels, it safeguards their health and well-being. Advanced personal dosimeters are being introduced lately by healthcare players as well. For instance, in 2023, Tracerco, which is one of the most leading brands for providing radiation monitoring equipment, announced the range of its next generation personal electronic dosimeters that will provide clients with a patented detection technology to enhance radiological safety performance.

North America to Dominate Medical Radiation Detection Market

Market share in terms of value is the highest in North America, which has emerged as the leading region in the medical radiation detection industry. High prevalence of cancer has led to high demand of diagnosis and monitoring which drives the need for advanced imaging technologies such as X-ray, CT, and MRI, which are facilitated by radiology. As per December 2022 CDC data, a significant portion of the United States population (60%) suffers from chronic illnesses, with 40% having multiple chronic conditions.

North America boasts a well-developed healthcare system, providing the necessary infrastructure and support for the adoption and integration of advanced radiology services which again makes it prone to become the largest market. Plus, increased government funding in healthcare, evidenced by the National Institutes of Health data showing a rise in the United States healthcare expenditure for biomedical imaging from USD 2.774 billion in 2022 to USD 3.101 billion in 2023, fuels advancements in radiation detection market. Leading players in the region, such as United Imaging Healthcare's launch of their 5.0T MRI scanner in March 2023, contribute to market growth by introducing innovative radiology tools that again promote the global medical radiation detection market.

Future Market Scenario (2024 – 2031F)

As time advances, so is technology. One of the biggest boons of technology in healthcare is integration of AI with radiology.The rising need to diagnose diseases using imaging procedures is met due to the availability of radiology. However, radiation when used in more amounts than required can be dangerous. It introduces the need for radiation detection devices which regulate and control the amount of radiation given to the patient. Also, it prevents the healthcare professionals from being exposed to it. Undoubtedly, radiology is the topmost segment in healthcare in terms of market size and shares. Growth of medical radiation detection market goes parallel to growth of radiology sector. It presents us with a high potential market to invest in. The government along with large pharmaceutical giants are coming together and introducing the most cutting-edge technology to the market. Medical tourism is one sector that is widely accepted in almost every nation, worldwide. The market’s expansion is crucial for the betterment of the healthcare industry on a holistic level. For instance, the National Health Expenditure Projections 2023–2024 predict that, due to the assumption that patient care patterns will return to pre-pandemic levels, growth rates in the United States health expenditures will be 5% this year and 5.1% in the next year.

Key Players Landscape and Outlook

There are a number of significant competitors in the competitive market of medical radiation detection. Presently, a number of the key competitors control the majority of the market share. These companies are leading the market share due to their continuous efforts toward R&D, technological advancements and drug development that is effective and reliable.

In November 2023, TeleDaaS PLC, a leading service provider of radiation detection, made its debut in the Radiological Society of North America. They have launched TeleDaaS to aid research and development in cancer. The goal of TeleDaaS is to revolutionize cancer therapy research and development by offering highly scalable, best-in-class dosimetry services that interface with current imaging workflows.

In November 2023, Mayo Clinic and GE Healthcare established a strategic partnership for research and product development initiatives aimed to improve patient and physician experiences with radiology and the delivery of innovative treatments.


1. Research Methodology
2. Project Scope and Definitions
3. Executive Summary
4. Global Medical Radiation Detection Market Outlook, 2017-2031F
4.1. Market Size & Forecast
4.1.1. By Value
4.1.2. By Volume
4.2. By Detector Type
4.2.1. Gas-Filled Detectors
4.2.1.1. Integrated Software Geiger—Muller Counters
4.2.1.2. Ionization Chambers
4.2.1.2.1. Dosimeters
4.2.1.2.2. Radiation Survey Meters
4.2.1.3. Proportional Counters
4.2.2. Scintillators
4.2.2.1. Organic Scintillators
4.2.2.2. Inorganic Scintillators
4.2.3. Solid-State Detectors
4.2.3.1. Semiconductor Detectors
4.2.3.1.1. Ionizing Radiation Detectors
4.2.3.1.2. Terahertz Radiation Detectors
4.3. By Product Type
4.3.1. Personal Dosimeters
4.3.1.1. Active Dosimeters
4.3.1.2. Passive Dosimeters
4.3.2. Area Process Dosimeters
4.3.3. Surface Contamination Monitors
4.3.4. Others
4.4. By End-user
4.4.1. Hospitals
4.4.2. Radiology Centers
4.4.3. Ambulatory Surgery Centers
4.4.4. Clinics
4.4.5. Others
4.5. By Region
4.5.1. North America
4.5.2. Europe
4.5.3. Asia-Pacific
4.5.4. South America
4.5.5. Middle East and Africa
4.6. By Company Market Share (%), 2023
5. Global Medical Radiation Detection Market Outlook, By Region, 2017-2031F
5.1. North America*
5.1.1. Market Size & Forecast
5.1.1.1. By Value
5.1.1.2. By Volume
5.1.2. By Detector Type
5.1.2.1. Gas-Filled Detectors
5.1.2.1.1. Integrated Software Geiger—Muller Counters
5.1.2.1.2. Ionization Chambers
5.1.2.1.2.1. Dosimeters
5.1.2.1.2.2. Radiation Survey Meters
5.1.2.1.3. Proportional Counters
5.1.2.2. Scintillators
5.1.2.2.1. Organic Scintillators
5.1.2.2.2. Inorganic Scintillators
5.1.2.3. Solid-State Detectors
5.1.2.3.1. Semiconductor Detectors
5.1.2.3.1.1. Ionizing Radiation Detectors
5.1.2.3.1.2. Terahertz Radiation Detectors
5.1.3. By Product Type
5.1.3.1. Personal Dosimeters
5.1.3.1.1. Active Dosimeters
5.1.3.1.2. Passive Dosimeters
5.1.3.2. Area Process Dosimeters
5.1.3.3. Surface Contamination Monitors
5.1.3.4. Others
5.1.4. By End-user
5.1.4.1. Hospitals
5.1.4.2. Radiology Centers
5.1.4.3. Ambulatory Surgery Centers
5.1.4.4. Clinics
5.1.4.5. Others
5.1.5. United States*
5.1.5.1. Market Size & Forecast
5.1.5.1.1. By Value
5.1.5.1.2. By Volume
5.1.5.2. By Detector Type
5.1.5.2.1. Gas-Filled Detectors
5.1.5.2.1.1. Integrated Software Geiger—Muller Counters
5.1.5.2.1.2. Ionization Chambers
5.1.5.2.1.2.1. Dosimeters
5.1.5.2.1.2.2. Radiation Survey Meters
5.1.5.2.1.3. Proportional Counters
5.1.5.2.2. Scintillators
5.1.5.2.2.1. Organic Scintillators
5.1.5.2.2.2. Inorganic Scintillators
5.1.5.2.3. Solid-State Detectors
5.1.5.2.3.1. Semiconductor Detectors
5.1.5.2.3.1.1. Ionizing Radiation Detectors
5.1.5.2.3.1.2. Terahertz Radiation Detectors
5.1.5.3. By Product Type
5.1.5.3.1. Personal Dosimeters
5.1.5.3.1.1. Active Dosimeters
5.1.5.3.1.2. Passive Dosimeters
5.1.5.3.2. Area Process Dosimeters
5.1.5.3.3. Surface Contamination Monitors
5.1.5.3.4. Others
5.1.5.4. By End-user
5.1.5.4.1. Hospitals
5.1.5.4.2. Radiology Centers
5.1.5.4.3. Ambulatory Surgery Centers
5.1.5.4.4. Clinics
5.1.5.4.5. Others
5.1.6. Canada
5.1.7. Mexico
*All segments will be provided for all regions and countries covered
5.2. Europe
5.2.1. Germany
5.2.2. France
5.2.3. Italy
5.2.4. United Kingdom
5.2.5. Russia
5.2.6. Netherlands
5.2.7. Spain
5.2.8. Turkey
5.2.9. Poland
5.3. Asia-Pacific
5.3.1. India
5.3.2. China
5.3.3. Japan
5.3.4. Australia
5.3.5. Vietnam
5.3.6. South Korea
5.3.7. Indonesia
5.3.8. Philippines
5.4. South America
5.4.1. Brazil
5.4.2. Argentina
5.5. Middle East and Africa
5.5.1. Saudi Arabia
5.5.2. UAE
5.5.3. South Africa
6. Market Mapping, 2023
6.1. By Detector Type
6.2. By Product Type
6.3. By End-user
6.4. By Region
7. Macro Environment and Industry Structure
7.1. Demand Supply Analysis
7.2. Import Export Analysis
7.3. Value Chain Analysis
7.4. PESTEL Analysis
7.4.1. Political Factors
7.4.2. Economic System
7.4.3. Social Implications
7.4.4. Technological Advancements
7.4.5. Environmental Impacts
7.4.6. Legal Compliances and Regulatory Policies (Statutory Bodies Included)
7.5. Porter’s Five Forces Analysis
7.5.1. Supplier Power
7.5.2. Buyer Power
7.5.3. Substitution Threat
7.5.4. Threat from New Entrant
7.5.5. Competitive Rivalry
8. Market Dynamics
8.1. Growth Drivers
8.2. Growth Inhibitors (Challenges and Restraints)
9. Regulatory Framework and Innovation
9.1. Patent Landscape
9.2. Regulatory Approvals
9.3. Innovations/Emerging Technologies
10. Key Players Landscape
10.1. Competition Matrix of Top Five Market Leaders
10.2. Market Revenue Analysis of Top Five Market Leaders (By Value, 2023)
10.3. Mergers and Acquisitions/Joint Ventures (If Applicable)
10.4. SWOT Analysis (For Five Market Players)
10.5. Patent Analysis (If Applicable)
11. Pricing Analysis
12. Case Studies
13. Key Players Outlook
13.1. Fortive Corporation
13.1.1. Company Details
13.1.2. Key Management Personnel
13.1.3. Products and Services
13.1.4. Financials (As Reported)
13.1.5. Key Market Focus and Geographical Presence
13.1.6. Recent Developments
13.2. Mirion Technologies Inc.
13.3. Thermo Fisher Scientific Inc.
13.4. AliMed Inc.
13.5. Radiation Detection Company (RDC) Inc.
13.6. Arrow-Tech, Inc.
13.7. Centronic, Ltd.
13.8. Nucleonix Systems (P) Ltd.
13.9. Alpha Spectra, Inc.
13.10. Micron Technology, Inc.
*Companies mentioned above DO NOT hold any order as per market share and can be changed as per information available during research work.
14. Strategic Recommendations
15. About Us and Disclaimer

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