medical grade touch screen monitors dicom free sample

Settings: Brightness, Contrast, Clock, Phase, H-position, V-position, Auto-Adjust, Aspect Ratio, Sharpness, Color Temperature, OSD Timeout, OSD Language, Volume, Mute, Recall Defaults, Audio Select, Power LED ON/OFF, Touch Thru, Touch Interface, DICOM

Settings: Brightness, Contrast, Clock, Phase, H-position, V-position, Auto-Adjust, Aspect Ratio, Sharpness, Color Temperature, OSD Timeout, OSD Language, Volume, Mute, Recall Defaults, Audio Select, Power LED ON/OFF, Touch Thru, Touch Interface, DICOM

DICOM (Digital Imaging and Communications in Medicine) is a standard format that enables medical professionals to view, store, and share medical images irrespective of their geographic location or the devices they use, as long as those devices support the format. DICOM images need to be viewed through specific software called DICOM viewers that can read and display the format. The images, along with the corresponding patient data, are often stored in a large database called the Picture Archiving and Communication System (PACS). The purpose of a DICOM application is to store information in the PACS about the imaging examination, along with patient details, and then when required, to view and interpret (and possibly edit) medical images that are retrieved from the PACS. DICOM images are unique in the fact that they contain patient information in addition to the image data.

There is actually no dearth of DICOM viewing software out there. Search online and you will find a multitude of options—some freeware, some paid, some targeted at medical students, others at seasoned experts, each with different specifications, systems requirements, add-ons, and capabilities. As a classic case of the paradox of choice, the abundance merely makes it difficult for healthcare professionals to choose the software that would be the best fit for their requirements. This is our endeavor in this article, to make the decision easier for you by presenting some popular viewers with useful features and very affordable pricing plans. In fact, most of them are free for basic use.

For instance, some software are meant only for basic viewing. Therefore, they do not have any additional features such as sharing or storage. Some applications have the ability to export data as JPEG or GIF files, which can be used in teaching and presentations. DICOM software for clinics can store images to a certain extent on mini-PACS servers. Some software also offer advanced features, like anonymization, which is particularly useful when conducting clinical research.

If you are a medical student, you may just be looking for a way to view and study clinical images. A full-fledged radiologist, on the other hand, would need high-speed software with specialized plug-ins and structured reporting. Furthermore, certain applications may be best suited to view images from specific body regions.

Most doctors and students today use not only their desktops, but also laptops, tablets, and smartphones interchangeably. The ideal DICOM application would allow access to the same data from multiple devices with convenience. You want a viewer that you can access from any device, any time.

Most DICOM applications today read common imaging modalities like CT, MRI, and ultrasound images. Features such as multiplanar reconstruction (MPR), particularly 3D reconstruction, are needed for treatment planning. Volume rendering, maximum and minimum intensity projections (MIPs) aid in diagnosis as well as in research. Image fusion, such as PET to CTs or PET to MRIs can also help in diagnosis and reporting.

The DICOM software must integrate with a PACS server that offers enough space to store an adequate volume of images along with patient data. The PACS server might be located in an institution, in which case the application must integrate to it directly, or it can be a cloud-based PACS system, which can be accessed online from anywhere. The latter is especially useful when images need to be stored and analyzed for research purposes.

Keeping the above purposes in mind, and allowing for ease of use and installation by end users themselves, we have compiled the following list that includes the most convenient, useful, and affordable DICOM viewers out there:

PostDICOM is one of the best DICOM viewers that offers almost all of the above features. It is compatible with Windows, Mac OS X, and Linux. It can be operated from android devices and iOS-based systems. PostDICOM comes with a cloud-based PACS, which allows you to access data from any device, anywhere, at any time. The viewer allows advanced image manipulation, such as 3D reconstruction, 3D volume rendering and MIP, and image fusion. It also offers an interface for creating reports, sharing files, and immediate uploading of all patient data to the cloud PACS.

Although paid subscriptions are available, the free trial version itself has several premium features. The cloud PACS offers free trial to its paid subscriptions, shares a month, and one or more user logins. These can be increased with different paid subscriptions. PostDICOM offers technical support for the free.

Horos is an open source DICOM viewer for Mac. It is actually the free version of an expensive DICOM viewer called Osirix MD, which is often considered to be the best DICOM viewer for Mac. It only runs on Mac OS, version 10.8 or higher. This software allows for most diagnostic techniques, including multiplanar reconstruction, maximum intensity projections, and volume rendering. It also has tools for manipulating images and making measurements.

A free version of Osirix MD, called Osirix Lite, is also available to users. However, it does not allowing editing of imaging metadata, and image modifications come with a watermark. While this is good to get a feel for the parent software, it is not intended for regular medical use.

The RadiAnt DICOM image viewer is a simple, fast platform that is compatible with Windows. It offers multiple features, including MPR, MIP, and image fusion. Images can be exported to JPEG, PNG, and other image formats. They can also be copy-pasted directly to presentations and word documents.

The application is just a viewer and does not offer storage space. Their website has a disclaimer explicitly stating that they do not have any certifications, and as such, the product is not intended for diagnostic use. However, it is handy for students and residents for studying medical images and research purposes.

The Navegatium DICOM viewer has been designed especially for touchscreen computers and tablets, and when used on these devices can be very fast and simple to use. It offers MPR, MIP, and simulated reconstructions. The layout and views can be customized as per user preferences. It can be directly integrated with PACS, but does not offer storage, importing and sharing.

It may be slightly awkward to use without a touchscreen. This application only runs on higher versions of Windows. It lacks advanced features, but is useful for basic use.

The Pro Surgical 3D application (from the Stratovan Group) is mainly targeted at surgeons, for surgical planning using their high quality 3D reconstruction feature. However, anyone can use this application to read and understand scans. It has the capacity to anonymize and de-identify patient details in scans, which is a must when the images are used in research, presentations or publications. They have an integrated customer support portal to aid in usage. The application also provides access to the Navegatium Knowledge Base—a comprehensive digital library of medical images.

The application allows both viewing and processing of DICOM images. It can generate structured reports, and allows basic measurements, annotations, and zooming in for images. MicroDicom does not offer advanced features such as MPR and volume rendering. It can be downloaded as a potable zip file that does not require installation. This allows it to be used on any device that has a Windows OS.

This is a lightweight application that is great for beginners who are learning to use a DICOM viewer. Its biggest advantage is that it can be run on multiple operating systems. It offers multiplanar views, MIP and volume rendering, but image editing and exporting are not possible.

This is a browser-based DICOM viewer, which means it cannot be downloaded, but can be accessed through any device with an internet browser—your laptop, phone, tablet, or even smart televisions. Only basic manipulation of the image (drag, zoom, contrast) can be done, and as this is view-only, export is not possible. The application requires some technical skill to navigate around, but videos and support is offered.

MANGO is an advanced DICOM application which requires some technical coding before it can be used. It has several advanced features, including conversion, anonymization and editing images. Other versions of Mango (Papaya and iMango) can be accessed from the browser directly or an Apple iPad. The application is under constant development, possible due to grants from the National Institute of Mental Health and the National Institute of Biomedical Imaging and Engineering. Therefore, it keeps improving in its functionality. Advanced options like behavioral analysis, disease analysis, and brain separation modalities make it particularly useful for neuromedicine. It does not offer cloud storage.

This is another lightweight application that is capable of viewing DICOM images. Escape EMV offers anonymizing and exporting features, but does not have many other advanced specs. It is available in multiple languages. Only a trial version is available free of cost, and commercial use of the software requires payment of a license fee.

IrfanView is an extremely simple yet effective image viewer that supports the DICOM format in addition to other image files. It does not boast the features of many of the above applications, but if your purpose is to simply view DICOM images, it is lightweight and easy to use. The software is only free for non-commercial purposes. If you intend to use it for your private practice or in a hospital setting, a license fee is applicable.

This is the free version of the paid software JiveX Review Client, and is meant to be used in educational and research activities. The viewer supports not only radiology images in the DICOM format, but also other medical data such as ECGs. The freeware does not allow users access to a PACS server or technical support. Although the viewer improves workflow, advanced manipulation of images is not possible with the free version.

It is a cloud-based DICOM viewer, and can be accessed from laptops, desktops, phones and tablets. It is very useful when a team of professionals needs to share DICOM images between them. NextCloud is available as a mobile app, and users can sync images, chat, and share images and notes with the app. However, it does not allow for image modification and analysis.

It is a powerful and fast DICOM viewer that is packed with many features. It enables reconstruction, volume rendering and image manipulation by offering several tools to carry out these functions. One unique spec of this application is its voice recognition technology, which helps users when viewing and retrieving files. Voice recognition also enables easy preparation of reports from the DICOM files. The viewer works better on systems with a touchscreen. The free version is only for a trial and purchase is required to access all features.

Miele LXIV is a free DICOM viewer for Mac operating systems. It has advanced features including MPR, MIP, volume rendering, and image fusion. In addition, it also allows 4D viewing of cardiac CTs. It is PACS-integrated and can send and receive files from a PACS database.

It is a free application that can access and view all DICOM images. The application allows you to sort images according to body parts. Images can be annotated, measured and animated. Advanced features are not available in the free version. The software cannot play videos.

It is a simple, basic application that can be used just to view DICOM files. The Lite is a free version of ORS Visual Pro, which is paid software. Small annotations and basic changes like track, zoom and reset are available in the free version. A search pane is also present to easily retrieve files. While MIP and MPR are available in the Lite version, volume rendering, 3D reconstruction and exporting is allowed only in the paid version.

The Orpalis DICOM viewing tool supports all DICOM files and has a simple interface. There is a dedicated forum for support and problem-solving. It is capable of animating multiple frames in a loop mode for easy viewing. Images can be captured and pasted to other presentations or documents.

MiViewer from Millensys is a simple DICOM viewer for Windows that does not require any setup. It has both image viewing tools and cine loop tools, and supports all DICOM file types. Unlike its paid version, Vision Tools Multiview, it does not support advanced features or allow PACS integration.

This is one of the few viewers that is compatible with Windows, Mac OS X, and Linux. It is an open source project that supports PACS. It has all the standard DICOM tools, but not many of the advanced tools required in medical diagnosis and research. The Pro version has advanced features like MPR and MIP.

This software, targeted at students, allows viewing and processing of DICOM files. It allows zooming, image orientation and adjustment, but not more advanced features. Online support is available.

Weasis is a powerful cross-platform DICOM viewer that can be integrated with PACS. It is meant for use by hospitals, as well as for research. It provides multi-language support and has advanced features including MPR, MIP, SUV measurements, and structured reports. It is also compatible for ECGs.

To help you choose the right application for your needs from this assortment of feature-packed yet affordable DICOM viewers, we’ve created a table that summarizes the essential features of each software:

The TRU-Vu MMZBTP-15.6G-XG is a 15.6” medical touch screen monitor. It conforms to UL 60601-1 Edition 3.1, and IEC 60601-1-2  4th Edition.  Our 15.6″ medical grade touchscreen is ideal for hospital operating rooms, medical carts, and medical imaging systems. Also found in fluoroscopy, endoscopy, OEM medical systems, PACS and other medical applications.  Additionally, this medical grade touch screenalso compatible with Automation DirectHMI.

Our widescreen 15.6″ medical touch screen monitor provides 1080p, 1920 x 1080 Full HD resolution. Additionally, the super-wide 178 x 178 viewing angles ensures clear, sharp images when viewed from nearly any angle. Thanks to its high resolution, brightness and high contrast ratio, our 15.6″ medical-grade touch screen provides razor-sharp, flicker free images. Consequently, this enables doctors and surgeons to make accurate, and timely, critical decisions. Fast response time and lag-free transmission of images ensure the most detailed images in the OR today.

The projected capacitive touch technology enables multi-touch, with up to 10 simultaneous touch points. Furthermore, the P-Cap touch screen can be activated via exposed fingers, or with a surgical glove. The screen is unaffected by dirt, grease or moisture on the glass surface. To help you guide you through the advantages of the 5 most common types of touch technology, see our tutorial on touch screen basics.Our convenient touch screen comparison chart will provide a quick overview of advantages and disadvantages of each type.

Our zero-bezel ABS enclosure features a single pane of glass across the entire front face of its 15.6″ medical-grade touch screen. Due to the absence of any raised-edge bezel (frame) around the front edges, this touch screen is extremely easy to clean (see Cleaning Instructions Guide) and improves overall hygiene. The bezel-less monitor enclosure eliminates the build-up of germs and contamination, as there is no bezel for them to reside beneath, as with standard enclosures. The rounded corners of the housing add a measure of comfort and safety, as well as improved aesthetics. This lightweight surgical display features rear VESA mount holes which enables easy mounting via spring arms, surgical booms or tabletop stands. Rear speakers are standard and can provide useful tones or alarms.

All our Medical displays are built without internal fans. A fanless design provides numerous important benefits. Reliability and durability are greatly increased, since one major moving part, the fan, which is subject to mechanical failure, is eliminated. Consequently, a fan-less design also provides a higher level of safety in sterile environments, as it eliminates the circulation of pathogens and dust. Lastly, a fan-less monitor is also quieter.

With over 200 LCD monitors and touch screens on our site, selecting the ideal monitor solution may be a bit overwhelming.To help narrow-down the choices, check out ourAdvanced Search Tool.For example, this enables you to filter by your own useful features. For instance, view all Medical-Grade displays only. Custom OEM LCD Displays and Private Label Monitors are also an option if you have very specific requirements.  Furthermore, visit our wide range of LCD monitor mounts and stands to complete your installation.

Remember, our team members are ready to help! We can determine the exact solution that will meet your specific needs. TRU-Vu medical displays will help provide crystal-clear images for your medical  projects. Call(847) 259-2344today to speak with one of our medical monitor specialists. Above all, we will listen.  It’s one of the things we do best.  Our professional advisors will ensure the monitor or touch screen you receive will be everything you had hoped it would for your medical imaging system.

All TRU-Vu Medical Grade monitors utilizes industrial-grade components and high-end LCD panels not found in retail/consumer-grade monitors. Therefore, this ensures superior image quality, improved performance and greater durability.

The TRU-VuMMZBTP-27G-XAG are  27” medical touch screen monitors. They conform to UL 60601-1 Edition 3.1, and IEC 60601-1-2 4th Edition.  Our 27″ medical touch screen display is ideal for hospital operating rooms, medical carts, medical imaging systems, fluoroscopy, endoscopy, OEM medical systems, PACS and other medical applications.

Our widescreen 27″ medical touch screen monitors provide 1080p, 1920 x 1080 Full HD resolution. The super-wide 178 x 178 viewing angles ensures clear, sharp images when viewed from nearly any angle. Our 27″ medical-grade touch screen features high resolution, brightness and high contrast ratio,. This ensures razor-sharp, flicker free images. It enables doctors and surgeons to make accurate, and timely, critical decisions. Fast response time and lag-free transmission of images ensure the most detailed images in the OR today. This is a 16:9 aspect ratio medical grade touch screen.

The projected capacitive touch technology enables multi-touch, with up to 10 simultaneous touch points for your medical imaging system. The P-Cap touch screen can be activated via exposed fingers, or with a surgical glove. The screen is unaffected by dirt, grease or moisture on the glass surface.

Our zero-bezel ABS enclosure features a single pane of glass across the entire front face of this 27″ medical-grade touch screen. Due to the absence of any raised-edge bezel (frame) around the front edges, this touch screen is extremely easy to clean (see Cleaning Instructions Guide) and improves overall hygiene. The bezel-less monitor enclosure eliminates the build-up of germs and contamination. There is no bezel for germs to reside beneath, as with standard enclosures. The rounded corners of the housing add a measure of comfort and safety, as well as improved aesthetics.

All our Medical displays are built without internal fans. A fan-less design provides numerous important benefits. Reliability and durability are greatly increased, since one major moving part, the fan, which is subject to mechanical failure, is eliminated. A fan-less design also provides a higher level of safety in sterile environments, as it eliminates the circulation of pathogens and dust. Lastly, a fan-less monitor is also quieter.

With over 200 LCD monitors and touch screens on our site, selecting the ideal medical monitor solution may be a bit overwhelming.To help narrow-down the choices, check out ourAdvanced Search Tool.For example, this enables you to filter by your own useful features. View all Medical-Grade displays only. Custom OEM LCD Displays and Private Label Monitors are also an option if you have very specific requirements.

Remember, our team members are ready to help! We can determine the exact solution that will meet your specific needs. TRU-Vu medical displays will help provide crystal-clear images for your medical  projects. Call(847) 259-2344today to speak with one of our medical monitor specialists. Above all, we will listen.  It’s one of the things we do best.  Our professional advisors will ensure the monitor or touch screen you receive will be everything you had hoped it would for your medical imaging system.

All TRU-Vu Medical Displays utilize industrial-grade components and high-end LCD panels. These are not found in retail or consumer-grade monitors. Therefore, this ensures superior image quality, improved performance and greater durability.

A medical display is a monitor that meets the high demands of medical imaging. Medical displays usually come with special image-enhancing technologies to ensure consistent brightness over the lifetime of the display, noise-free images, ergonomic reading and automated compliance with DICOM and other medical image quality standards.

Displays for digital pathology are designed especially for image viewing in pathology. For example, they offer color spaces that are adapted to digital slides, or fast refresh rates for smooth and clear images during panning or zooming. They deliver consistent, detailed images and their image quality doesn’t degrade over the years.

Medical displays for radiology, mammography and pathology require an advanced display controller that can faultlessly process the large, highly detailed files that come with medical imaging. They can handle intensive, long-term use, and process large images correctly and with minimal delay. In these ways, they can support the medical professional’s workflow. Furthermore, advanced display controllers can support technologies to better detect small details and work faster.

In surgery, especially image-guided, it is vital that images are rendered instantly, with minimal delay. This ensures better hand-eye coordination for surgeons, because what they see on the screen matches what happens in real time.

Surgical displays range from near-patient monitors to large-screen OR displays. Most surgical displays can be mounted onto surgical arms or booms, with cables neatly hidden, and the screen is usually scratch-resistant. They can also allow for easy cleaning and disinfection.

A dental display is a high-bright, medical monitor designed for viewing of dental images, such as X-rays of teeth, bone, nerves, and soft tissue. With dental displays, subtle abnormalities or concealed anatomical structures in the oral and maxillofacial regions become more visible, compared to consumer displays. This makes it easier for dentists to detect dental pathologies. Dental displays come in various shapes and forms, from cleanable review displays to high-end displays designed specifically for dental diagnosis.

You don’t always need a high-resolution diagnostic display in a clinical environment. You might be looking for a display you can use for various non-diagnostic activities, such as enabling easy access for clinical staff to electronic medical records, or medical images. Clinical review displays help you making medical information available across an enterprise, reliably and with consistent image quality. They can offer additional functionalities for use in medical environment, such as cleanable design that can stand alcohol cleaning agents. All our clinical review displays are DICOM-compliant.

As the number of people receiving examinations increases and exam locations expand, the medical industry’s demand for endoscopic examination systems and displays has also grown. “Displays play an especially critical role in endoscopic examinations,” said Deputy General Manager Li Kun-Hai of the Business Department of Welmore Co., Ltd. He said that a good display should be capable of clearly displaying the images captured by endoscopes to help doctors make correct judgments. Consequently, Welmore Co., Ltd. has chosen to partner with Advantech to release the Fujifilm endoscope system, equipped with Advantech’s 24” PAX medical display which is capable of satisfying the stringent medical imaging requirements of endoscopic examinations.

Welmore, founded in 2001, is a renowned supplier of medical equipment in Taiwan. Furthermore, Welmore has endeavored to introduce the latest medical equipment to Taiwan from abroad to increase the overall standard of healthcare. For example, Fujifilm’s endoscope system, which is distributed by the company, has earned the praise of many gastroenterologists.

Originally, Welmore used another display with the Fujifilm endoscope system, but after discovering Advantech’s PAX medical displays in 2021, they realized that the performance, price-performance ratio, and design of Advantech’s display were far superior. Consequently, they made the decision to switch to Advantech.

Advantech’s PAX displays boast excellent resolution and clear images, but also show moving images without any ghosting. This makes them a perfect fit to meet the standards of doctors making evaluations. Deputy General Manager Li Kun-Hai pointed out that before Welmore officially started its partnership with Advantech, the equipment was sent to the client side for testing, and received an overwhelmingly positive response from doctors. Therefore, it’s clear that Advantech’s PAX medical displays are capable of satisfying doctors’ requirements in the areas of contrast, color, and ghosting.

Senior Sales Manager Anita Lee of Advantech noted that after the launch of the PAX medical display, Advantech has continued to listen to feedback from doctors and nurses to further develop the product and integrate the latest advancements. In 2022, the product’s brand image was updated based on the word “TIGER” to emphasize features that offer increased efficiency and service quality to healthcare professionals.

Each of the 5 letters in “TIGER” represents a feature of Advantech’s PAX medical displays. T as in “Touch” stands for the panel’s user-friendly touchscreen design; I stands for “Integration”, referring to the display’s high degree of image integration and DICOM support, which has been tested on various medical instruments, endoscopes, and electric scalpels; G stands for “Glorious”, referring to the display’s rich gamut of 1.07 billion colors as well as support for grayscale X-ray image displays and 14-bit LUT grayscale processing, thereby providing precise images that increase diagnostic accuracy; E stands for “ESD certification” for a flicker-free display; finally, R stands for “Resolution” and represents support for 4K/FHD super-high resolutions.

Advantech’s PAX displays are reasonably priced and far more competitive than medical displays with similar specifications from other brands. For the Fujifilm endoscope equipment, Welmore set their target audience as regional hospitals or personal clinics by providing solutions that correspond to customer budgets. Welmore’s combination of Advantech PAX medical displays optimizes endoscope examination systems and better meets the requirements of their target market.

The third key feature is design. Deputy General Manager Li Kun-Hai believes that the white exterior of Advantech PAX medical displays exudes minimalism and high quality, and they fit in well in medical environments and present an image of professionalism.

After more than a year of this excellent partnership, Deputy General Manager Li Kun-Hai hopes that future applications of Advantech’s PAX medical display can expand to Welmore’s other endoscope examination systems. After all, image accuracy is a critical factor in determining the results of endoscopic examinations and Advantech’s PAX medical displays offer accurate endoscopic images which can also improve Welmore’s market reputation and the quality they offer. This helps both companies achieve the goal of “utilizing technology integration in professional healthcare for the health of citizens”.

The growth of medical imaging technologies has revolutionized the healthcare sector. This term is synonymous with a wide range of techniques used to produce images of various parts of the human body. X-ray radiography, fluoroscopy, medical ultrasonography, elastography, endoscopy, tactile imaging, thermography, and medical photography are some examples of medical imaging technologies. These powerful imaging techniques are widely used for making a non-invasive assessment of injuries; early detection of diseases; or to study different phases of diseases or during surgeries. The devices used for implementing these techniques are driven by different technologies, but they all have a thing in common – a medical-grade monitor.

A medical monitor display is designed under stringent regulations and they possess improved designs over consumer-grade displays. These displays are equipped with image-enhancing technologies to improve the clarity of medical images. How do they differ from consumer-grade displays?

Industry Standards: The key difference between commercial monitors and medical monitors lie in their governing standards. It is well-known that medical industry is monitored and governed by stringent standards such as FDA. So, medical monitors are also built in adherence to FDA standards. Another thing is they must comply with UL/EC60601-1 guidelines. IEC-60601 refers to the series of technical standards that outline the effectiveness and safety of medical electrical equipment. Against this, the commercial monitors can be marketed or built to standards of the industry where they are used. Most times, these standards only focus on the quality, there may not be much references to luminance, display, or other characteristics.

Resolution: Medical displays are offered in various resolutions including 4K resolution (3840 x 2160 pixels), which enable medical professionals to view images accurately and provide precise diagnosis results. These higher resolution displays such as 4K enable users to focus on fine details of image without zooming or tilting the image, without compromising on the quality. The 4K medical monitors also possess high Pixels Per Inch (PPI), which adds to the sharpness of images. Many medical displays also assure the benefit of multimodality imaging, which means a user can view grayscale and color images simultaneously on a single screen, without switching displays. However, these benefits are not assured by commercial displays.

DICOM (available on 4K): All medical grade displays are required to comply with DICOM requirements, which helps assure their accuracy. DICOM stands for Digital Imaging and Communications in Medicine. This is the international standard to store, transmit, process, print, and display medical imaging information. This standard applies to all images whether viewed on the monitor, saved on a desktop or printed as a hardcopy. This also includes specifications for medical monitors, mobile devices, and other smart devices used in various fields of medicine. The medical monitors meeting DICOM requirements may possess the following characteristics:

Uptime: As said before, medical LCD displays need to comply with stringent medical standards such as DIACOM, AAPM, MQSA, and so on. Compliance to these standards also assure maximum uptime. Most of these displays are designed for working 24/7. Nowadays, many advanced medical monitors also offer remote calibration, which assures maximum performance without interrupting regular workflow.

Productivity: Owing to long product lifecycle, low maintenance, and quality assurance, most medical displays assure low total cost of ownership (TCO) than regular consumer displays. Also, many of these displays are backed with a warranty period of 3 to 5 years.

Microtips Technology USA has introduced the latest set of IEC 60601 certified medical monitors and tablets. Is that all? No. Microtips is also offering a broad range of healthcare solutions including surgical and clinical 4K healthcare grade monitors, as well as healthcare grade tablets and mobile computers for mobile healthcare solutions. The following features of these monitors make them popular:

Easy Connectivity Assured: All HD and 4K healthcare grade monitors are provided with multiple inputs and mounts for easy connectivity to any source or existing design.

Custom Specifications: The experts at Microtips Technology know that medical imaging devices have different requirements. So, they work closely with clients to design various types of healthcare grade multi-touch monitors that are customized to suit their application requirements.

The Microtips team is ready to help you with any queries on IEC 60601 certified medical LCD monitors or healthcare grade mobile solutions provided by them. All you have to do is contact the team today to discuss the requirements.

There is a paid version of Horos called ‘OsiriX MD’, which is produced by Pixmeo, however it is expensive so not ideal for basic teaching purposes, although has great functionality.  Pixemo also produce a free demo version called ‘OsiriX Lite’, however there are major limitations placed on this including pop-ups asking you to upgrade to the paid version, performance restrictions, image viewing restrictions and inability to edit the meta-data attached to DICOM images – for example you can’t easily re-order series within a study, which may be important if you are preparing cases for teaching or examinations.  It is for these reasons that we do not list OsiriX Lite in our recommendations.

In a study by Choudhri et al., an iPhone 3G is equipped with a display with a resolution of 420 × 380 pixels with 163 pixels per inch. Assessment of DICOM computed tomography datasets was performed on 16 or 64 slice helical scanners after intravenous contrast administration. The image resolution was 512 × 512 pixels. Image data were first transferred to a MacBook Pro computer, then loaded into the OsiriX DICOM viewer and anonymized. Later, the images were transferred to an iPhone 3G device. Image analysis was performed by three radiologists, previously trained to use both the device and software. They assessed presence of aortic dissection, intramural hematoma, pseudoaneurysm, aortic transection or active extravasation. Diagnoses made on the mobile device were compared to the assessments made on the PACS workstation by radiologists specializing in vascular imaging [13].

De Maio et al. compared magnetic resonance imaging (MRI) examinations of the knee joints on a mobile device and a standard PACS station. The mobile device used in the study was an iPhone 3GS, iOS 4.0 with a screen diagonal of 8.9 cm and a display with a resolution of 320 × 480 pixels. Software used on the mobile device was OsiriX DICOM viewer, version 1.1.4. A second device was a Hewlett-Packard Z800 workstation, equipped with the Windows XP pro 2002 service pack 3, connected to an HP LP3065 monitor with a screen diagonal of 76.2 cm and a display with a resolution of 2560 × 1600 pixels. The eFilm Workstation 3.0 program was used to view images on the workstation. The images for the examination were obtained using a 1.5-T MRI machine, Signa Excite, software version 12.0, with a multichannel coil dedicated to the knee joint. Examinations were performed according to the standard knee MRI protocol. The layer was 4 mm thick and the field of view was 14 × 14 cm. The examinations were assessed by two radiologists with longstanding experience in diagnosing diseases of the musculoskeletal system on MRI images. Researchers worked independently, in a blinded and randomized manner. Examinations were displayed at random. The first researcher assessed all 50 images. The second researcher, in order to ensure credibility, described 25 randomly selected studies from the entire pool of studies analyzed. To minimize the risk of distorting results due to researchers remembering the content of previously analyzed examinations, the time interval between the interpretation of the same test on the mobile device and the PACS station was at least two months. A report of the examination description was written according to the standard formula used by the orthopedic surgeon as well as the time needed for the examination description was measured, rounded to the nearest minute [14].

Abboud et al. compared two devices in their study: an iPad2 with screen diagonal 9.7” with a resolution of 1024 × 768 pixels, maximum brightness 410 cd/m2 and contrast ratio 962:1 and as a comparison monitor, an IMac LCD with screen diagonal 17”, 2560 × 768 pixels resolution, maximum brightness 375 cd/m2 and default contrast ratio 1000: 1. The iMac’s DICOM image viewer was OsiriX Dicom and the iPad 2’s was OsiriX HD. The study used a collection of 240 chest X-rays from the tuberculosis screening program. Of these 240, 200 cases were originally reported negative, and 40 were positive. All studies were anonymized and prepared for interpretation in random order. Examinations were evaluated by a group of five radiologists whose task was to assess binary (positive or negative) presence of radiological features characteristic for tuberculosis. The first device to evaluate diagnostic images was selected randomly for each researcher. After at least 1 week researchers assessed images on the second device. The readings were taken in similar lighting conditions in the same room [15].

Carrasco et al. used the following devices and software as readers for CT scans: PACS medical grade LCD monitor “Planar PX212M”; Consumer grade LCD monitor “HP Compaq LA2205wg”, CB-Works software; MacBook Pro 13, OsiriX DICOM reader software; “IPad-4”, OsiriX DICOM reader software. Operators were to evaluate 32 CBCT (Cone Beam Computed Tomography) scans made with the CBCT Hitachi CB MercuRay using the standard departmental protocol (120 KV and 15 mA). Prior to evaluation, the images were anonymized and randomly numbered. Using an external storage device, DICOM data were transferred to the target device used in the study: Hewlett-Packard xw8200 Microsoft Windows XP, version 2002, Pack 3, (on a PACS workstation); HP Compaq 8200 Elite Microsoft Windows XP professional, version 2002, Pack 3; MacBook Pro, Mac OS X, version 10.8.3. The data were then imported into software (CB-Works, OsiriX). The PACS monitor was used as the gold standard. The iPad 4 was connected to a MacBook via a wireless network with the help of an application supporting a remote desktop (Pocket Cloud). In addition, the iPad and the stylus were secured with a clear plastic film to simulate the sterility conditions of the operating theater. The images were viewed and assessed by operators under standardized light and sound conditions. To simulate the conditions of a dental practice, images displayed on a tablet equipped with the OsiriX program were viewed in a room with fluorescent lighting. The operators used the tools provided by the programs including magnification, contrast brightness, cross-section cutting tools and length measurement. The region of interest (ROI) was the edentulous areas of the mandible and maxilla around the molars and premolars. The diagnostic quality of the devices was checked by the study participants by performing quantitative and qualitative measurements, other qualitative measures and the device resolution essential to determine pathology [16].

The Ortho Mobile study by Vetter et al. focuses on the usage of mobile devices and specialized software by orthopedists for viewing radiological images in clinical settings. An iPad mini 2 tablet was used due to a screen size sufficient to evaluate the imaging tests, but small enough to fit in the apron pocket. The software was selected in terms of its ability to work offline. The function of exchanging messages with the help of messenger was also noted. The selected application—mRay—was created for reading and analyzing images on mobile devices in the DICOM format. The software consists of the actual application (client component) and the application server. The task of the application server is to retrieve data from the PACS database, encrypt and compress. Then, these data are sent to the mobile device—their further reading after downloading can take place without any network connection. The mRay application is a CE-certified medical tool. The communication platform, which is part of the application, enables (in addition to the exchange of text and audio messages) the sharing of DICOM images or their fragments between users. Doctors participating in the study were trained in using the software. The results of operating the device were recorded by completing an online questionnaire daily [17].

Brehm et al. evaluated the diagnostic quality of the mRay image viewing software and a classic radiology workstation. One experienced neuroradiologist (>5 years of experience) and one resident (>1 year of experience) appraised the anonymized cases of 50 patients (there were multiple images of each of the patients) separately on two handheld devices (iPhone 7 Plus, MED-TAB) equipped with mRay Software and on a GE PACS workstation. The iPhone 7 plus had 128 GB of flash memory and a 5.5-inch diagonal screen with 1920 × 1080 pixels (luminance = 625 cd/m2). The MED-TAB had 16 GB of flash memory and a 13.3-inch diagonal screen with 1920 × 1080 pixels (luminance > 250 cd/m2). They were DICOM Part 14 greyscale standard display function-certified. GE PACS was connected to two medical-grad 21-inch liquid crystal displays (RX250, EIZO), both with a resolution of 1000 × 1600 pixels and a luminance of 400 cd/m2. To minimize the likelihood of recalling the image, each case was reviewed on each of the three devices with at least a 12-week interval. Both reviewers were asked to view the images in a location with ambient lighting below 100 lux. Both physicians were also asked to evaluate the diagnostic quality of all three devices on a five-point ordinal scale regarding detection of large-vessel occlusion (LVO), intracranial hemorrhage (ICH), early ischemic signs and overall safety of the diagnosis [19].

North America Medical Display Market, By Technology (LED-Backlit LCD Display, CCFL-Backlit LCD Display, TFT LCD Display And OLED Display), Panel Size (Under 22.9" Inch Panels, 23.0"- 32.0" Inch Panels, 27.0-41.9 Inch Panels and Above 42 Inch Panels), Viewing Mode (2D and 3D), Megapixel (UP TO 2MP, 2.1–4MP, 4.1–8MP and above 8MP), Resolution (4K, Ultra Full HD, Full HD and Others), Display Type (Wall Mounted, Portable, Modular), Imaging Technology (Touch Screen, Scratch Resistant Font Glass, Failsafe Mode, Cleanable Options, Softglow & Spotview And Others), Display Color (Colour, Monochrome), Aspect Ratio (16.09, 21.09, 4.03), Component (Hardware and Services), Application (Consultation, Diagnostic, Surgical/Interventional, Telehealth, Teaching / Practice, Fetal Monitoring, Dentistry, Point Of Care, Patient-Worn Monitoring And Others) End User (Hospitals, Clinics, Nursing Facilities, Diagnostic Laboratories, Imaging/Radiology Lab, Laboratory, Rehabilitation Centers And Others), Distribution Channel (Direct Tender, Retail Sales and Others) - Industry Trends and Forecast to 2029.

The main reasons for the growth of the medical display market is the rising demand for minimally invasive treatments (MIT) due to multiple benefits such as less post-operative pain, fewer operative, and major post-operative complications, shortened hospital stay, faster recovery times, less scarring, less stress on the immune system, smaller incision, and for some procedures it reduced operating time and reduced costs as well.

Data Bridge Market Research analyzes that the medical display market is expected to reach the value of USD 464.46 million by 2029, at a CAGR of 6.5% during the forecast period. This market report also covers pricing analysis, patent analysis, and technological advancements in depth.

By Technology (LED-Backlit Lcd Display, CCFL-Backlit LCD Display, TFT LCD Display And OLED Display), Panel Size (Under 22.9" Inch Panels, 23.0"- 32.0" Inch Panels, 27.0-41.9 Inch Panels and Above 42 Inch Panels), Viewing Mode (2D and 3D), Megapixel (UP TO 2MP, 2.1–4MP, 4.1–8MP and above 8MP), Resolution (4K, Ultra Full HD, Full HD and Others), Display Type (Wall Mounted, Portable, Modular), Imaging Technology (Touch Screen, Scratch Resistant Font Glass, Failsafe Mode, Cleanable Options, Softglow & Spotview And Others), Display Color (Colour, Monochrome), Aspect Ratio (16.09, 21.09, 4.03), Component (Hardware and Services), Application (Consultation, Diagnostic, Surgical/Interventional, Telehealth, Teaching / Practice, Fetal Monitoring, Dentistry, Point Of Care, Patient-Worn Monitoring And Others) End User (Hospitals, Clinics, Nursing Facilities, Diagnostic Laboratories, Imaging/Radiology Lab, Laboratory, Rehabilitation Centers And Others), Distribution Channel (Direct Tender, Retail Sales and Others)

BenQ, ALPINION MEDICAL SYSTEMS Co., Ltd, Nanjing Jusha Commercial &Trading Co,Ltd, COJE CO.,LTD., Axiomtek Co., Ltd., Dell Inc., HP Development Company, L.P., Reshin, Onyx Healthcare Inc., Teguar Computers., Shenzhen Beacon Display Technology Co., Ltd., Rein Medical, STERIS., Barco., Hisense., Sony Corporation, Advantech Co., Ltd., LG Electronics., Sharp NEC Display Solutions, Koninklijke Philips N.V., EIZO INC., Novanta Inc., FSN Medical Technologies., Quest, Ampronix., Siemens Healthcare GmbH, Panasonic Corporation, among others.

A medical display is a monitor that meets the high demands of medical imaging. It usually comes with special image-enhancing technologies to ensure consistent brightness over the lifetime of the display, noise-free images, ergonomic reading and automated compliance with digital imaging and communications in medicine (DICOM) and other medical standards.

The development of medical imaging technologies has progressed healthcare, providing powerful diagnostic tools, supporting the non-invasive assessment of injuries and internal issues, and enabling diseases to be detected far earlier than ever before. Medical displays are preferred over consumer displays when used for medical imaging. The reason is simple: medical displays meet set requirements for image quality, medical regulations, and quality assurance.

The future of medical display devices are based on the developments in artificial intelligence (AI) and data analytics. Medical devices are advancing disease management by allowing clinicians to personalize medicine like never before. These technologies provide revelatory insights into individual patients in real-time.

The main reasons for the growth of the North America medical display market is the rising demand for minimally invasive treatments (MIT) due to multiple benefits such as less post-operative pain, fewer operative, and major post-operative complications, shortened hospital stay, faster recovery times, less scarring, less stress on the immune system, smaller incision, and for some procedures it reduced operating time and reduced costs as well.

Minimal invasive surgery is an excellent approach for diagnosing and treating a wide range of thoracic disorders that previously required sternotomy or open thoracotomy. The prevalence of chronic diseases requiring surgery has increased worldwide. Due to the many advantages of minimally invasive treatment, many patients prefer it. In addition, vascular and endovascular surgeries, neurological and spinal surgeries, orthopedic trauma care, and cardiac surgeries are performed in hybrid operating rooms. This feature allows hospitals to perform advanced surgical operations, which increases the demand for medical displays. In addition, increasing healthcare costs and the number of pathology and radiology laboratories drive the demand for medical monitors.

Governments and non-profit organizations in several countries mainly focus on developing health infrastructure to minimize disease burden and provide better health services. In addition, the adoption of technologically advanced medical devices, screens, monitors, and various other devices has increased. All such factors are likely to create favorable opportunities for market growth during the forecast period. In addition, heavy investments by key players in innovative product launches and updated features in the coming years can also boost the market.

Moreover, the increasing demand for cost-effective healthcare services, increasing demand for technical solutions, increasing high mobility of information, increasing government initiatives and incentives, and increasing funding for high-quality medical displays in hospitals and research centers are expected to drive these healthcare facilities in the market. Medical software infrastructure has formed the basis for recent advances in medical displays, digital medical libraries, and management information systems. These factors are expected to drive the growth of the North America medical display market.

As the market-focus drive toward the production of orally deliverable dosage forms, there is a constant struggle to develop appropriate formulations of new molecules that allow oral administration and, simultaneously, ensure the drug has optimal bioavailability in patients. To overcome this, pharmaceutical excipient manufacturers are developing easier products and reducing development time and cost. The development of medical display technologies has changed the healthcare industry, providing diagnostic tools, telehealth, providing support for non-invasive treatment, allowing diseases to be assessed and allowing the diseases to be detected earlier.

The launch of technological developments in medical display devices is enhancing the efficiency of the medical display and increasing the ease of using medical display devices. The surge in technological applications in medical display devices would result in less workforce and swift diagnosis and recovery of diseases. In the future, artificial intelligence technology will replace the medical display market. This factor is expected to act as an opportunity for North America medical display market growth in the forecast period.

The high cost of display devices and the high implementation is the major factor restraining market growth, specifically in countries where the reimbursement scenario is poor. Most healthcare facilities in developing countries, such as hospitals and diagnostic centers, cannot afford these devices due to the high installation and maintenance costs and due to the high cost of these medical equipment’s and low financial resources, healthcare facilities in emerging countries are reluctant to invest in new technologically advanced systems. These factors can hamper the digitalization in healthcare facilities and impact the adoption of advanced technologies for diagnosis and analysis.

In June 2022, EIZO Corporation launched RadiForce MX243W – a 24.1-inch 2.3 megapixel (1920 x 1200 pixels) monitor. The 24.1-inch 2.3 megapixels (1920 x 1200 pixels) monitor has been designed for careful monitoring and diagnosis of complete physiology of patient system in clinics and hospitals. The launch resulted in the addition of a new medical device to the portfolio and offered exceptional market purity

In May 2021, Barco launched the Nio Fusion 12MP medical display. The product launch resulted in an enhanced product portfolio and a rise in sales and expansion of medical display product line across North America and Europe

North America medical display market is categorized into thirteen notable segments which are based on technology, panel size, viewing mode, megapixel, resolution, display type, imaging technology, display color, aspect ratio, component, application, end user and distribution channel. The growth among segments helps you analyze niche pockets of growth and strategies to approach the market and determine your core application areas and the difference in your target markets.

On the basis of technology, the medical display market is segmented into LED-backlit LCD display, CCFL-backlit LCD display, TFT LCD display and OLED display.

On the basis of panel size, the medical display market is segmented into under 22.9" inch panels, 23.0"- 32.0" inch panels, 27.0-41.9 inch panels and above 42 inch panels.

On the basis of imaging technology, the medical display market is segmented into touch screen, scratch resistant font glass, failsafe mode, cleanable options, softglow & spotview and others.

On the basis of application, the medical display market is segmented into consultation, diagnostic, surgical/interventional, telehealth, teaching / practice, fetal monitoring, dentistry, point of care, patient-worn monitoring and others.

On the basis of end user, the medical display market is segmented into hospitals, clinics, nursing facilities, diagnostic laboratories, imaging/radiology lab, laboratory, rehabilitation centers and others.

The medical display market is analyzed and market size information is provided technology, panel size, viewing mode, megapixel, resolution, display type, imaging technology, display color, aspect ratio, component, application, end user and distribution channel.

North America is expected to dominate the market as it is the largest medical device market in the world. The U.S is expected to dominate the market due to rise in disposable income of the people.

The medical display market competitive landscape provides details by competitor. Details included are company overview, company financials, revenue generated, market potential, investment in R&D, new market initiatives, production sites and facilities, company strengths and weaknesses, product launch, product trials pipelines, product approvals, patents, product width and breath, application dominance, technology lifeline curve. The above data points provided are only related to the company’s focus on the medical display market.

Some of the major players operating in the,market are BenQ, ALPINION MEDICAL SYSTEMS Co., Ltd, Nanjing Jusha Commercial &Trading Co,Ltd, COJE CO.,LTD., Axiomtek Co., Ltd., Dell Inc., HP Development Company, L.P., Reshin, Onyx Healthcare Inc., Teguar Computers., Shenzhen Beacon Display Technology Co., Ltd., Rein Medical, STERIS., Barco., Hisense., Sony Corporation, Advantech Co., Ltd., LG Electronics., Sharp NEC Display Solutions, Koninklijke Philips N.V., EIZO INC., Novanta Inc., FSN Medical Technologies., Quest, Ampronix., Siemens Healthcare GmbH, Panasonic Corporation, among others.

Thanks to the high 2 Megapixels (colour) resolution, a strong contrast ratio of 1000:1 and stable brightness of up to 260 cd/m2, the monitor offers excellent image quality. Even the differences between the finest details are shown – regardless of your viewing angle. This is a great advantage if multiple physicians are looking at the screen.

A touch screen allows monitors to be operated by finger touch or by stylus. Typing, dragging, rotating, minimising – everything works quickly and directly by touch.

The MS236WT-A contains reliable capacitive touch technology (PCAP) that detects movements with very high precision. Hence you can easily capture even small writing and character input via the screen.

The display extends right up to the bezels – this means that the entire touch surface can be used without disruptions right up to the edges, which is particularly convenient for swiping and scrolling motions.

The monitor can detect up to ten simultaneous touches, which means that multiple individuals can operate the monitor at the same time. Furthermore, the touchscreen is equipped with hand ball recognition. While writing, users can place their hands or arms on the monitor without accidentally triggering an input.

The monitor is equipped with technology that calibrates the touch sensitivity to minimise incorrect touch response due to environmental factors and electromagnetic noise. This ensures that the screen maintains accurate touch interaction during use.

Users can easily turn touch detection on or off by pushing the button conveniently located on the monitor"s outer rim. A button is located on two sides of the monitor for easy access.

The multitouch interface is supported by standard Windows 11, 10 and 8.1 drivers. You can operate the touch panel without additional drivers by simply connecting the USB cable.

The monitors in the RadiForce series have powerful functionalities and characteristics that provide medical staff with increased ease of use and efficiency when performing diagnostics.

EIZO measures and adjusts each tone of grey carefully so that the monitors comply with the DICOM® standard when delivered from the factory. The result is a particularly consistent gradation of grey tones, allowing for optimal radiological clinical reviews.

EIZO guarantees an extra-long warranty for medical monitors. EIZO monitors offer the greatest possible investment security and at the same time avoid service costs.

The EIZO graphics card MED-XN51LP optimally supports the features, functions and settings of the RadiForce MS236WT-A. It enables precise diagnosis and can control several monitors simultaneously. EIZO offers technical support and warranty service for the graphics card.

OsiriX HD is a full DICOM image viewer for iOS so that you can access to medical images, download them, and manipulate them using your iPhone or your iPad. Zoom, pan, rotate and adjust the contrast of images through the multipoint touch screen interface.

It works with all imaging modalities : ultrasound, CT scanner, MRI, PET, etc. in their native standard DICOM format used by the medical/scientific industry. It’s designed to work seamlessly with any DICOM compatible software, including PACS, medical workstations, acquisition modalities. It also supports communications through the iOS built-in VPN for secure and encrypted connections.

This iOS application can also be used as a helper application for other iOS applications: it allows to read DICOM datasets received by emails or in Safari, or to visualize DICOM datasets stored in Dropbox folder, for example. It also supports a built-in URL scheme protocol (osirix://) for easy integration in RIS, HIS, or PACS environment.