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In an ever more digital world, digital radiography is rapidly replacing analog film-based methods.1 A growing number of dentists–widely considered to have a market penetration of around 60% in the United States–have already incorporated the technology, which can offer numerous advantages over film-based radiography,2-6 including speed of viewing; image enhancement capabilities; ease of sharing digital files for second opinions and co-diagnosis; the potential for reduced patient radiation exposure in keeping with the ALARA (as low as reasonably achievable) principle;7,8 and permitting better patient understanding of their oral conditions.6 It also requires less space and eliminates costs and inconvenience associated with maintaining and discarding processing fluids.9
Other reasons digital radiography is rapidly becoming the norm relate to pending government requirements and standards for information transfer. Electronic health records (EHR) are becoming a reality. As of January 2015, dentists who participate in Medicare and Medicaid may be eligible for incentive payments for adopting an EHR system that is accepted by the Centers for Medicare & Medicaid Services (CMS).10 This is under a Health Information Technology for Economic and Clinical Health (HITECH) provision of the American Recovery and Reinvestment Act of 2009 known as Meaningful Use. Dentists who are Meaningful Use-eligible may face Medicare payment penalties if they fail to implement a certified EHR and attest for Meaningful Use successfully.11 For dentists who are not eligible to participate in Meaningful Use programs, it is possible that individual states may still impose EHR requirements.11 It is advisable for all dentists to use EHR for efficiency within their own office as well as the broader healthcare enterprise irrespective of potential monetary incentives or penalties that might apply. Then, too, to consider is the need for electronic file exchange using DICOM (Digital Imaging and Communication in Medicine), a standard advocated by the ADA for handling, storing, printing, and transmitting medical imaging information about patients, procedures, and the diagnostic images themselves, which enables the integration of scanners, printers, workstations, servers, and file exchange between DICOM-compatible offices.12,13
Among digital technology options that are useful for the general practitioner are 2D intraoral and extraoral systems including panoramic imaging (both solid state or photostimulable phosphor), as well as 3D systems, mainly cone-beam computed tomography (CBCT). All have their respective advantages and disadvantages, which—along with their features—are discussed below.2,6,9,14-24
Whether traditional film-based or digital, an intraoral radiography method is needed by virtually all general practices for diagnosing a variety of dental problems. Due to their ability to capture detail, intraoral digital imaging methods are especially suitable for diagnosing periapical lesions, caries, and periodontal disease.
The digital advantages of image enhancement capabilities (Figure 1) and transmission can be achieved either with one-step methods, where the image is sent from a solid-state digital sensor placed in the patient’s mouth to the computer monitor, or a two-step method, where first the image is taken using a photostimulated phosphor (PSP) plate that is processed using a laser scanner that sends the image to the computer monitor.
There are two main types of detectors presently in use for solid-state 2D dental radiography—charge-coupled device (CCD) and complementary metal–oxide–semiconductor (CMOS). Both involve the placement of a digital sensor in the patient’s mouth, as described above. CMOS chips tend to provide a wider recording latitude and are not subject to picture element blooming, which can occur with overexposure and saturation of a CCD chip.
Advantages of solid-state intraoral radiography include high image quality, which is at least equivalent to analog film exposed and processed optimally, and to photostimulable phosphor images. Solid-state sensors are robust and rarely need to be repaired or replaced, while film can only be used once, and the photostimulable phosphors used for intraoral imaging tend to wear and scratch over time with use. Disadvantages of solid-state intraoral x-ray sensors include greater expense initially to buy the sensor, possible patient discomfort caused by the rigid sensor, and the learning curve involved in its use, including achieving more patient-friendly placement. There are also issues involving disinfection of the sensor between usage and the placement of plastic barriers that are needed with solid-state intraoral sensors.
Photostimulable Phosphor Method
The use of photostimulable phosphors can be less expensive in an office that requires multiple detectors. It also involves less of a learning curve because they are placed in the mouth in a similar way to the film-based method. There is placement of a thin flexible phosphor plate in the patient’s mouth using a “film” holder; then the image is transferred from the plate to the computer using scanning by a solid-state red laser, photo multiplication, and digitization. The flexible plates can be more comfortable for patients compared to rigid oral sensors, and larger photostimulable phosphor plates also can be used with film-based panoramic systems where the image film intensifying screens are removed from the cassette. However, intraoral photostimulable plates do scratch and periodically require replacement. Also to consider is that the extra processing step with images means it is somewhat less “instant.”
Extraoral Radiography Methods
Both solid-state and photostimulable phosphor radiography methods are available for extraoral use. Except for issues related to their placement in patients’ mouths, which is not a factor in extraoral radiography, their relative advantages and disadvantages are similar to those described above—ie, solid-state digital is more convenient and slightly more expensive; extraoral photostimulable phosphor imaging is less convenient and can be less expensive, especially because there is no need to replace the x-ray generator. For extraoral digital radiography using photostimulable phosphors, film cassettes can be simply modified by removing the film image intensifier screens.
Like intraoral digital imaging, extraoral methods eliminate the need for a darkroom; they also have the ability to readily enhance and analyze images, and they offer the convenience of image storage, duplication, and retrieval. With extraoral radiography, the image file size is larger than that generated by intraoral imaging, which can be reduced by lossless compression techniques that facilitate storage without compromising the diagnostic quality of the image.9,20 As computer power has grown and digital storage has come down in price, the need for compression of files has declined.
A digital panoramic radiograph (Figure 2) is indicated for circumstances in which intraoral imaging is not practical, as in patients who cannot open their mouths due to trismus or in those who cannot tolerate having a sensor or film in their mouth due to severe mucositis following radiation therapy for cancer. Advantages of panoramic imaging are that it quickly provides broad coverage of facial bones and teeth, it is convenient for both dental practitioner and patient, and is a helpful visual aid in patient education and case presentation.
Drawbacks of panoramic imaging are the cost—$25,000 to $85,00019—and that vertical beam angulation is not adjustable. Also, like a traditional panoramic machine, the digital unit requires dedicated operatory space, so there’s no space savings other than not needing a darkroom.
CBCT is indicated for the following: implant planning; developing surgical guides; general observation; finding the correct number of canals in abscessed teeth requiring endodontic treatment; in some cases, for orthodontic planning for patients with asymmetries or who need surgical procedures; for evaluation of impacted teeth or TMJ; and as an adjunct for intraoral imaging. Perhaps the most important CBCT advantage is that it offers a “third dimension” for diagnostic accuracy (Figure 3).22
Other benefits include: its short scan time; nearly immediate availability of images; compatibility with practice management software; ability to identify a variety of incidental findings, such as carotid artery calcifications; and facilitate patient communication/education. Like any imaging in dentistry, CBCT should only be used for dental purposes, but incidental findings should be recorded when they are present. CBCT should not be used specifically for screening for carotid calcification, as Duplex Doppler ultrasound is the method of choice for inspecting blood clots in the carotids. When calcification is found in the carotids, or other conditions of general health importance are found, the patient should be referred to the appropriate physician for further follow-up and treatment if needed. While there is a learning curve for reading the full image volumes, there are services available for this. Like CBCT, it is extraoral, so its advantages include that it is more comfortable for patients and can be used in patients who cannot tolerate having a sensor or film in their mouths. It can also be used when intraoral scanning is not practical—eg, for a panoramic bitewing.
It should be emphasized that CBCT should not be considered a replacement for intraoral imaging in the general practice office.19,24 In that regard, pertinent disadvantages are that it offers insufficient detail for diagnosing caries, periodontal disease, and small lesions in the bone. This is due to CBCT beam hardening artifacts and streaking caused by metallic restorations. Additional considerations include its cost, that it requires dedicated operatory space, and that CMS requires facility accreditation and CE for its reimbursement in Medicare or Medicaid patients.25 Also to consider is that it delivers a higher radiation dose than the full-mouth series (FMX) performed with round collimation.24
With the goal of providing comprehensive, custom care for every patient, costs and benefits of the above technologies can be weighed in determining an appropriate combination of available options (intra- and extraorally).13 Hybrid systems made up of differing combinations of available options offer flexibility to enable the clinician to best address clinical situations. An example would be having a panoramic system—with either storage phosphor plates or a direct digital panoramic system—and using direct extraoral imaging with both direct sensors and a PSP systems for intraoral use.
Practice Scope and Finances
Also to factor into the purchase of new technology are future as well as current practice needs. This includes the task performed—eg, implants, caries detection, root canals—which may well be determined by the patient population. For example, practices with a large proportion of Medicare or Medicaid patients should be aware that CMS requires that private practices using point-of-care CT scanning devices obtain accreditation, which includes continuing education requirements, in order to be eligible for reimbursement by CMS.19,25
Budgetary considerations may include the flexibility of purchase, whether old and new technology will be used concurrently, and tax implications—eg, the Section 179 deduction26 that offers a tax break at the end of the fiscal year for purchase of equipment.
Staff should also be included in the decision-making process. Practitioners should solicit their input, assess how new equipment will impact their responsibilities, and discuss training requirements—especially with significantly advanced technology and techniques. Together, the team should evaluate training options. They should also focus on existing skill sets. Is the staff technology/computer savvy? Is the staff strong on insurance coding/management?13
The office layout, too, must be considered. Although saving space is a benefit of digital systems, which don’t require the chemicals and processing needed by film-based systems, that is only the case if film-based systems are eliminated entirely. Some things to keep in mind: panoramic and CBCT units need a dedicated area and workstation to control the acquisition device, and the digital scanner that acquires and processes images with an indirect system using PSP must be attached to a computer workstation.27
Researching products that meet the practice’s needs with the above factors in mind should be multifaceted, and may involve online sources, journals, or CE courses. Especially valuable is discussion—by all team members, including assistants and hygienists—with study groups, professional societies, and colleagues. Of course, the practitioner and key personnel should also speak to and meet with manufacturers’ representatives prepared to address crucial questions. It is critical to find objective data and unbiased resources to determine the best system for the individual practice.
Practices considering a particular system may be able to take it for a “trial run” to determine if it is appropriate for their needs prior to purchasing. This enables the dental team to ask questions and express their concerns, as they also can during initial training by the company after system purchase and installation.28
What You Need to Know
Before purchasing a system, it is important to learn in advance as much as possible—especially about the issues that may not come immediately to mind.13
Some Questions to Ask:
- Will existing technology need to be upgraded or replaced?
- Is the software compatible with the current practice management system?
- Does the manufacturer provide training? (This is especially important with CBCT due to CMS requirements of 4 hours from the manufacturer as well as 20 hours from elsewhere initially.)
- What type of hardware or software support is available?
- Does it include technical support? Equipment maintenance? Software upgrades?
- Is it provided by the manufacturer or is it outsourced?
- Is there 24/7 support or is access limited?
It is also important to find out if the system is DICOM-compliant to ensure that images can be acquired, saved, and transferred properly.23 DICOM-compliant digital radiographic systems use file formats that are universally accepted, which permits image transfer or teleradiography for various purposes.23 When it comes to storing and sharing data with digital radiographic systems, it is essential to follow HIPAA regulations. All patient health information and data, especially radiographic images, need to be maintained and protected.23 The ADA Standards Committee on Dental Informatics has prepared a Technical Report outlining the protocol on how DICOM-conformant images can be securely emailed in a HIPAA-compliant manner.28,29
Three key considerations when installing new technology are wiring, space, and equipment location.27
Although wireless technology is advancing, the fastest, most reliable, and most secure method today is a wired connection for solid-state digital scanners. Space considerations revolve largely around workflow of patients and staff. (Switching to digital can improve workflow because digital radiography systems can be integrated into imaging and practice management software. Patients can receive a faster diagnosis, and professionals can spend more time with their patients.)
As for equipment location, it should facilitate ease of use and efficient workflow and stored to enable convenient access. Monitor location for image viewing depends on where and when images are viewed and by whom—eg, by the dentist while performing a procedure or by the patient for education and consultation purposes. A 21-inch-wide or larger monitor allows for better viewing of radiographs, compared to the standard No. 2-size film.27 The recommended minimum contrast ratio of the monitor should be 500:1,27 and because solid-state intraoral systems sensors are used in multiple operatories, they should have a quick connect/disconnect interface and be located and stored appropriately.27 They should also be easily disinfected.
It is prudent to plan for space and wiring in anticipation of future technology and equipment purchases.
A properly designed and installed network enables movement of files between operatories, workstations, offices, practices, and insurers (Figure 4). Viewing the same information on different computers or workstations requires a computer network that enables sharing information on multiple machines. The value of a properly designed and secured network cannot be overstated. An improperly designed and installed network is the cause of many of the problems reported in daily system use.
The place where images are saved and stored for use on workstations should be a central location to facilitate retrieval, data protection, simultaneous access to data stored on multiple drives, and backup.6 Practitioners should be aware that Redundant Array of Independent Discs (RAID), a backup system commonly used in companies and practices, will not protect against catastrophic loss (eg, fire, flood, etc). Therefore, it is necessary to have off-site backup, which is easily facilitated by digital technology.27
For off-site backup, practitioners must choose between storage based online—ie, in the “cloud”—or removable via an external hard drive that is removed from the office each day.27
HIPAA level security is necessary for all protected health information including diagnostic images.
Practitioners should also have a plan in place for ongoing maintenance concerning how the system will be maintained and supported as well as installed. It is important that the manufacturer be able to provide information technology as well as hardware support. Annual contract agreements are particularly important to protect the investment in upper level items such as CBCT units.
Employee Training/Continuing Education
While only a dentist or specialist can diagnose radiographs, the taking of radiographs may involve roles and responsibilities for the entire team, all of whom should receive training to familiarize them with new equipment and its appropriate uses.13 Personnel who will be using the equipment should receive training on how to use it properly for patient comfort, safety, and maximum effectiveness—including physical positioning of the patient (extraoral), positioning of the sensor (intraoral), software operation (image adjustment, etc.), and minimizing patient radiation exposure in keeping with the ALARA principle.8
Transitioning to a digital system can seem daunting, and early training with the technology is the key to overcoming fear and hesitation. But the advantages of having a properly planned system cannot be understated. They include: security of available backup and off-site archiving; security mechanisms to identify original images and differentiate them from altered images; integrated storage with access to images through practice management software systems; perfect radiographic duplicates to accompany referrals; interoperability of the Digital Imaging and Communications in Medicine (DICOM) file format; and the ability to tag information such as a patient identifier, date of exposure, and other relevant details.29,30
To prepare for future technology, practitioners should periodically re-evaluate the needs of the practice and available technology and consider phasing out and replacing traditional technology with digital options. They should also make an effort to remain abreast of technology that can improve efficiency, patient care, and adherence to compliance requirements.
Because every practice is different, new technology should be assessed in terms of how it can improve current methods or resolve problems such as bottlenecks and inefficiencies in the practice workflow.
As oral healthcare evolves into a medical and wellness model, and all healthcare records turn digital, the clinician’s ability to stay current with high-quality diagnostic information will be central to the next level of patient care.
Allan G. Farman, BDS, PhD, DSc (Odont), has no relevant financial relationships to disclose.
1 Eshraghi T, McAllister N, McAllister B. Clinical applications of digital 2-D and 3-D radiography for the periodontist. J Evid Based Dent Pract. 2012;12(3 suppl):36-45.
2.Wenzel A. A review of dentists’ use of digital radiography and caries diagnosis with digital systems. Dentomaxillofac Radiol. 2006;35(5):307-314.
3. White SC, Pharoah MJ. Oral Radiology: Principle and Interpretation. 6th ed. St. Louis: Mosby-Year Book Inc; 2009:78-80.
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6. Watson JA. A perspective on digital radiography. Inside Dentistry. 2011;7(6):100-104.
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11. American Dental Association. Electronic Health Records. http://www.ada.org/en/member-center/member-benefits/practice-resources/dental-informatics/electronic-health-records. Accessed June 6, 2016.
12. DICOM. Wikipedia website. Wikipedia. http://en.wikipedia.org/w/index.php?title=Digital_Imaging_and_Communications_in_Medicine&oldid=154283703. Accessed May 16, 2014.
13. Benjamin S. Planning for success: Moving forward with digital dental radiography. Inside Dentistry. 2013;9(spec iss 4):2-6.
14. Dias da Silva PR, Martins Marques M, Steagall W Jr, et al. Accuracy of direct digital radiography for detecting occlusal caries in primary teeth compared with conventional radiography and visual inspection: an in vitro study. Dentomaxillofac Radiol. 2010;39(6):362-367.
15. Borg E, Gröndahl HG. Image plate systems differ in physical performance. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2000;89(1):118-124.
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17. Digital Radiography Systems: Comparison of Sensor Technologies. American Dental Association website. http://www.ada.org/sections/scienceAndResearch/pdfs/0607_digital_sensors.pdf. Accessed June 7, 2016.
18. Dale Miles. Learn Digital website. http://learndigital.net/articles/part1.htm. Accessed May 16, 2014.
19. Tuleya S. Breaking down today’s radiographic systems. Inside Dentistry. 2013;9(spec iss 4):8-11.
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21. Alshehri MA, Alamri HM, Mazen MM. CBCT applications in dental practice: A literature review. Dental Tribune website. http://www.dental-tribune.com/ articles/specialities/general_dentistry/3615_cbct_applications_in_dental_practice_a_literature_review.html. Accessed May 16, 2014.
22. Braun X, Ritter L, Jervøe-Storm PM, Frentzen M. Diagnostic accuracy of CBCT for periodontal lesions [abstract]. Clin Oral Investig. 2014;18(4):1229-1236.
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25. How to obtain accreditation for point-of-care CT scanning devices. Carestream Dental website. http://www.carestream.com/solutions/otolaryngology-allergy-whitepapers.html. Accessed May 16, 2014.
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30. ADA Technical Report No. 1048. Attachment of DICOM Datasets Using E-Mail in Dentistry. Chicago: American Dental Association; 2011. http://www.ada.org/en/science-research/dental-standards/standards-committee-on-dental-informatics/standards-technical-specifications-and-technical-reports. Accessed May 16, 2014.
About the Author
Allan G. Farman, BDS, PhD, MBA, DSc (Odont)
Oral and Maxillofacial Radiologist
Professor Emeritus, Radiology and Imaging Sciences
University of Louisville
Independent Consultant in Maxillofacial Imaging Science
Allan G. Farman, BDS, PhD, DSc (Odont), holds doctorates in oral and maxillofacial pathology (PhD) and in oral and maxillofacial radiology (DSc), both from the University of Stellenbosch, South Africa. He has graduate degrees in education (EdS, higher education administration) and business administration (MBA with distinction) from the University of Louisville, Kentucky, where he is professor emeritus of radiology and imaging sciences in the Department of Surgical and Hospital Dentistry, School of Dentistry, and an adjunct professor of anatomical sciences and neurobiology and clinical professor of diagnostic radiology in the School of Medicine until last year. A diplomate of the American Board of Oral and Maxillofacial Radiology, Dr. Farman is the founder of the International Congress on Computed Maxillofacial Imaging, and was the 11th president of the International Association of DentoMaxilloFacial Radiology. He was the First Honorary President for the Latin American Congress on DentoMaxilloFacial Radiology, held in Brazil in 1996. He is a member of the DICOM International Congress Organizing Committee.