Difference between revisions of "Ultrasonography in Periodontology"
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Ultrasonography in dentistry is a novel approach to diagnosing inflammation, specifically periodontal tissues (hard and soft tissue) and disease. An accurate dental diagnosis requires imaging and clinical evaluation. This technology is a level 3 technology with the unique identifier “3US - Ultrasound”. While this may not replace other types of medical imaging needed for an accurate dental diagnosis, it is a non-invasive technology that can be used for patient monitoring as well and enhances diagnostic capabilities. Early studies demonstrate uses in wound healing and tissue maturation. Other technologies that would be at level 3 are radiographs, intraoral scanners, and cone beam computed tomography. This technology can be further broken down into six level 4 identifiers: 4TD, 4CPU, 4PW, 4SC, 4CT, and 4EN (see DSM Allocation for descriptions of identifiers). | Ultrasonography in dentistry is a novel approach to diagnosing inflammation, specifically periodontal tissues (hard and soft tissue) and disease. An accurate dental diagnosis requires imaging and clinical evaluation. This technology is a level 3 technology with the unique identifier “3US - Ultrasound”. While this may not replace other types of medical imaging needed for an accurate dental diagnosis, it is a non-invasive technology that can be used for patient monitoring as well and enhances diagnostic capabilities. Early studies demonstrate uses in wound healing and tissue maturation. Other technologies that would be at level 3 are radiographs, intraoral scanners, and cone beam computed tomography. This technology can be further broken down into six level 4 identifiers: 4TD, 4CPU, 4PW, 4SC, 4CT, and 4EN (see DSM Allocation for descriptions of identifiers). | ||
Indication: Dental disease is typically diagnosed through clinical and radiographic evaluation. Not only does this leave a patient exposed to radiation, but this model is reactive rather than preventive. The use of ultrasound in dentistry as an imaging modality is novel. Currently, it is used for wound healing research but we propose developing a POC model with appropriate resolution that could be used at several check ups throughout the year to track inflammatory biomarkers. This noninvasive technology could be beneficial in preventing disease. | |||
Technology: Electricity is sent to the transducer which has piezoelectric crystals. Piezoelectric crystals convert the electrical signal into a sound wave. The soundwave then travels through a gel medium into a patient’s tissue. The sound waves then bounce back into the transducer and the signal is then generated and processed by the computer processing unit (CPU). Once it has been processed, it is sent to the graphic processing unit and displayed on a screen for the user to interpret. | |||
==Design Structure Matrix (DSM) Allocation== | ==Design Structure Matrix (DSM) Allocation== | ||
Revision as of 18:33, 5 November 2024
Technology Roadmap Sections and Deliverables
Roadmap Overview
Ultrasonography in dentistry is a novel approach to diagnosing inflammation, specifically periodontal tissues (hard and soft tissue) and disease. An accurate dental diagnosis requires imaging and clinical evaluation. This technology is a level 3 technology with the unique identifier “3US - Ultrasound”. While this may not replace other types of medical imaging needed for an accurate dental diagnosis, it is a non-invasive technology that can be used for patient monitoring as well and enhances diagnostic capabilities. Early studies demonstrate uses in wound healing and tissue maturation. Other technologies that would be at level 3 are radiographs, intraoral scanners, and cone beam computed tomography. This technology can be further broken down into six level 4 identifiers: 4TD, 4CPU, 4PW, 4SC, 4CT, and 4EN (see DSM Allocation for descriptions of identifiers).
Indication: Dental disease is typically diagnosed through clinical and radiographic evaluation. Not only does this leave a patient exposed to radiation, but this model is reactive rather than preventive. The use of ultrasound in dentistry as an imaging modality is novel. Currently, it is used for wound healing research but we propose developing a POC model with appropriate resolution that could be used at several check ups throughout the year to track inflammatory biomarkers. This noninvasive technology could be beneficial in preventing disease.
Technology: Electricity is sent to the transducer which has piezoelectric crystals. Piezoelectric crystals convert the electrical signal into a sound wave. The soundwave then travels through a gel medium into a patient’s tissue. The sound waves then bounce back into the transducer and the signal is then generated and processed by the computer processing unit (CPU). Once it has been processed, it is sent to the graphic processing unit and displayed on a screen for the user to interpret.