The global X-ray detector market size was USD 5.90 Billion in 2021 and is expected to register a revenue CAGR of 7.2% during the forecast period. Increasing technological innovation and launch of effective x-ray equipment and rising demand from various end-use sectors such as military and defense are key factors driving market revenue growth over the forecast period. Conventional x-ray detectors only record images in flat, rectangular 2D shapes. Currently, both medical and industrial fields rely heavily on 3D digital x-ray imaging. Inspection, such as finding hairline fractures or leaks in pipes, airplanes, and military equipment, are applications in the mechanical area. In the past, scientists have employed flex processing, which is a popular imaging technique, to photograph irregularly-shaped objects. Flex processing creates a flexible detector backplane by using a flexible substrate as the framework for various electrical layers. The structure is then finished by an attachment of a deposited scintillator layer (the element that transforms x-rays into visible photons).
A conformal detector on a surface is challenging since the scintillator layer limits true flexibility despite the flexibility of backplane. As a result, researchers are currently looking for new 3-D x-ray imaging techniques. For example, ASU researchers have created a technique for employing conformal x-ray sensors to take pictures of 3D surfaces.
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The scintillator layer is pre-molded or pre-shaped into different 3D geometries, and the detector is then finished by attaching the backplane. The pre-molded scintillator enhances the backplane’s fit, resulting in a more durable and robust detector overall. By conforming to a surface of an object and capturing minuscule details, the detector can reduce the amount of imaging while improving visibility and resolution. In conclusion, a pre-molded scintillator effectively allows the detector to conform to different objects.
3D X-ray image technology is also used for the detection of illegal wildlife trafficking. The Department of Agriculture, Fisheries, and Forestry (DAFF), the Department of Climate Change, Energy, the Environment and Water (DCCEEW), Rapiscan Systems, and the Taronga Conservation Society Australia have joined forces to stop the illegal smuggling of wildlife through the mail and traveler luggage pathways. Illegal animal trafficking poses a serious threat to Australia Due to potential introduction of pests and illnesses that could have an adverse impact on the environment, human and animal health, and biosecurity.
The market for x-ray detectors is expanding due to innovation. In June 2021 for instance, engineers of Duke University demonstrated a prototype X-ray scanning device that reveals both the structure and the chemical composition of an object. The method has the potential to revolutionize a variety of industries, such as cancer surgery, pathology, health screenings, and geology due to its outstanding resolution and accuracy.
Rapid technological advances and growing investments in R&D activities for developing facilities are also driving revenue growth of the market. For example, academic and commercial scientists use synchrotron light source PETRA III high-brilliance X-ray facility to study the structure and behavior of matter at atomic and molecular levels in a variety of fields, including clean energy technologies, drug development, healthcare, structural biology, and nanotechnology, as well as food and agricultural sciences. Germany-based biotech business BioNTech, best recognized for its effective mRNA vaccine against coronavirus infection, ran a series of X-ray scattering studies at the PETRA III beamline P12 of the EMBL. The PETRA III project has assisted industry users in gaining new insight into the inner workings of standard AAA batteries. PETRA IV and the transformation of the PETRA storage rings into an ultralow-emittance synchrotron source are in the planning stages. The ultimate 3D process microscope will be made available to scientists and engineers by PETRA IV, which will produce beams of tough X-rays with unprecedented coherence characteristics that can be focused down to the nanometer regime.
Driver: Rising investments in healthcare infrastructure and digital imaging technology for early detection
Heart disease continues to be the biggest cause of mortality globally and in the U.S. In every 40 seconds, a heart attack fatality occurs, according to the Centers for Disease Control and Prevention (CDC) and the economic cost of it is estimated to be USD 229 billion. More effective dietary and pharmacological therapies are being established by new surgical techniques and medical gadgets. With the help of advancements in cardiac imaging, caregivers may encourage early identification and intervention strategies. Heart disease is being combated by the global scientific and medical community in a variety of methods, including by creating novel surgical techniques and medical technologies as well as more effective dietary and pharmaceutical therapies. However, developments in medical imaging themselves could help medical professionals’ better address the heart health epidemic. Doctors can now see in 3D imaging due to advanced medical imaging, which offers previously unattainable images of the heart and vascular system. These developments are enhancing diagnostic and prognostic skills of medical professionals, allowing them to better assist patients who are experiencing heart failure as well as recognize and evaluate cardiac issues much earlier.
Restraint: Issues related to X-ray scanners and lack of radiologists
Scanners that perform full-body scans produce a digitized, stripped image of each passenger boarding a flight, ensuring airport security. This ensures that no passengers are in possession of hazardous materials or chemicals. Elevated levels of X-ray exposure, however, can worsen inherited conditions, increase the probability of cardiovascular and cancer disorders, and cause the lens of the eye to become cloudy. X-ray detectors at airports are prohibited in some European nations and are expected to restrain revenue growth of the market.
One of the unacknowledged problems in healthcare is the shortage of radiologists across the globe. Of the 7.9 billion people on the planet, 5.2 billion (or more than two-thirds) do not have access to one. A significant contributing cause to the escalating problems in pulmonary healthcare is the lack of this skill set. This is hampering revenue growth of the market over the forecast period.
Some Key Takeaways:
Based on type, the global X-ray detector market has been segmented into gas-filled, scintillation, and semiconductor. The semiconductor segment revenue is expected to account for largest revenue share over the forecast period. In contrast to other detector types such as gas detectors or image plates, semiconductor detectors have an exceptional ability to combine high speed, spatial resolution, and sensitivity. In many experiments at synchrotron facilities, semiconductor x-ray detectors for images are used. Moreover, rising (R&D) activities are also driving revenue growth of the segment. On 14 September 2022 for example, phase I Small Business Innovation Research (SBIR) funding was given to Sydor Technologies, a world leader in sophisticated x-ray detectors, for the creation of an ultra-fast, radiation-hardened hybrid- Complementary Metal-oxide-semiconductor (CMOS x-ray detector for high-energy x-ray research. The U.S. Department of Energy also is providing funding of USD 200,000 to the company. This funding is the first in a series that will lead to the development of next-generation of ultra-fast x-ray imagers for innovative laser diagnostics applications. The criteria for a reliable commercial prototype, appropriate for a wide variety of scientific applications, will be defined by Sydor Technologies using existing prototype sensing instruments and electronics created at national laboratories. Scientists will be able to see incredibly fast events in nuclear science, diffraction, and spectroscopy that are currently practically unattainable with the help of developed high-performing and reliable detectors.
Based on application, the global X-ray detector market is segmented into industrial, medical, security, veterinary, and others. The medical segment is expected to register rapid revenue growth rate in the market during the forecast period. Rising research activities for the development of AI-powered x-ray technique for identifying cancer, tuberculosis, and issues in the organs is contributing to revenue growth of the market. According to researchers, the new x-ray technique that works in conjunction with a deep-learning Artificial Intelligence (AI) system for detecting explosives in luggage may be able to spot potentially fatal early-stage cancers in humans. The AI is extraordinary technology and is capable of recognizing these substances even when they are hidden inside other things. This method may be employed in medical settings, particularly for cancer detection. X-rays can be a very powerful medical tool, but there are also some health hazards associated with them. Researchers have now created a new, shorter, more sensitive, and more secure x-ray detector to address this issue. For example, a group of scientists from Los Alamos National Laboratory and the Argonne National Laboratory has developed an x-ray detector that minimizes radiation exposure by using incredibly thin layers of the heavy element-rich material PEROVSKITE in place of conventional silicon. The sensitivity of these perovskite layers is also 100 times greater than that of conventional detectors. The researchers also claim that this development could advance astrophysical research as well as medical technology.
Based on end-use the global X-ray detector market is segmented into hospitals & clinics, Original Equipment Manufacturers (OEM), military & defense, diagnostic centers & laboratories, and others. The military & defense segment is expected to register significant revenue CAGR due to rising demand for advanced X-ray detectors for the detection of explosions. For example, when explosives are concealed inside electronics and other objects, it might be difficult to locate them using conventional x-ray procedures. The most recent work from the University College London (UCL) teams is really encouraging. It blends new X-ray imaging with AI and has enormous potential for Non-Destructive Testing (NDT) applications, including crack detection and the incredibly difficult issue of danger identification in hand luggage. The UCL team hid tiny quantities of explosives, such as Semtex and C4, within electrical devices such as computers, hair dryers, and smartphones to closely mimic backpack of a traveler. The products were placed inside bags along with chargers, toothbrushes, and other utensils. This experiment revealed that the new method was 100% accurate at detecting explosives in test environments.
Based on regional analysis, the market in North America accounted for largest revenue share in 2021 owing to presence of major manufacturers such as Varex Imaging, General Electric Company, and others in the region. High demand for minimally invasive procedures, a well-established healthcare sector, broadening clinical uses for X-ray detectors, and rising demand for early diagnosis are also contributing to revenue growth of the market in the region. Furthermore, increase in the elderly population base, expanding knowledge about the radiography system, favorable government initiatives, and substantial expenditure on R&D is also driving revenue growth in the region.
The X-ray detector market in the Asia Pacific market is expected to register fastest revenue CAGR owing to rapid adoption of 3D and digital radiology. The significant potential that the 3D X-ray algorithm has in preventing the trafficking of exotic wildlife, safeguarding agricultural sectors of Asia Pacific, and preserving its distinctive natural environment. With the future potential for global uses, this innovative technology is a priceless supplement to our current biosecurity and wildlife detection technologies at Australian international boundaries. Australian researchers have discovered that smuggled wildlife concealed in luggage or other goods can be located using a combination of 3D X-ray technologies and AI algorithms. For three categories of wildlife such as lizards, birds, and fish, the team developed a 3D-scanned “reference library” that they used to “train” AI algorithms to recognize the creatures. With a wrong hit rate of just 1.6%, the AI was able to detect objects 82% of the time.
The market in Europe accounted for second-largest revenue share in 2021. This is attributed to availability of advanced healthcare infrastructure coupled with rising research and development. On 9 September 2022 for example, AI Innovation Lab for Medical Imaging has been established in collaboration between Erasmus MC, University Medical Center Rotterdam, and Qure.ai, a leading provider of health technology. The three-year duration of the initial program will be used to perform in-depth research on the ability of AI algorithms to detect anomalies in both infectious and non-infectious disease states. The objective is to comprehend the possible applications of AI in Europe and advise clinicians on the best ways to employ the technology in accordance with their unique needs. Healthcare systems in Europe have experienced financial strain due to the pandemic. Resources are limited since it is difficult to find radiologists and specialized experts. Adopting AI can lessen the burden on clinicians and offer sufficient early warning systems and continuing monitoring of anomalies. Qure is already benefiting from progressive detection and automated anomaly identification, where AI may offer a more precise and effective study of tumors.
The competitive landscape of the global X-ray detector market is moderately consolidated with few major companies operating on global and regional levels. Major companies are engaged in product development and strategic alliances to expand their respective product portfolios and gain a robust footprint in the global market. Some major companies in the market report include Varex Imaging, Trixell, FUJIFILM Holdings America Corporation, Konica Minolta, Inc., PerkinElmer Inc., General Electric Company, Rayence, Teledyne Digital Imaging Inc., Agfa-Gevaert Group, Carestream Health, Hamamatsu Photonics K.K. and its affiliates, and Analogic Corporation.
Some recent developments are as follows:
- On 11 July 2022, the mKDR Xpress Mobile X-ray System will be compatible with Konica Minolta Healthcare Americas, Inc.’s ground-breaking Dynamic Digital Radiography (DDR) technology, which enables the imaging of anatomy in motion. The transportable system will also work with AeroDR Glassless High Definition Detector, the most recent advancement in wireless flat panel X-ray detector technology. With both approaches, clinicians can make better use of X-rays, the most widely used diagnostic imaging technique and frequently the first imaging test a patient has. At Konica Minolta’s exhibit at the Association for Medical Imaging Management (AHRA) 2022 Annual Conference in Phoenix, these fresh developments in X-ray technology will be unveiled.
Segments Covered in the report
This report offers historical data and forecasts revenue growth at a global, regional, and country-level, and provides analysis of the market trends in each of the sub-segments from 2022 to 2030. For the purpose of this report, Reports and Data has segmented the global X-ray detector market based on type, technology, panel size, portability, application, end-use, and region:
X-ray Detectors Market Report Scope
Segments covered By Type Outlook, Techology Outlook, Panel Size Outlook, Portability Outlook, Application Outlook, End-use Outlook, Regional Outlook
By Type Outlook
By Techology Outlook
Flat-Panel Detectors (FPDs)
Computed Radiography Detectors
Charge-Coupled Device Detectors
By Panel Size Outlook
By Portability Outlook
By Application Outlook
By End-use Outlook
Hospitals & Clinics
Original Equipment Manufacturers (OEM)
Military & Defense
Diagnostic Centers & Laboratories
Middle East & Africa
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