BACKGROUND: This article discusses how to integrate clinical and administrative workstations into your dental practice from the planning phase to the implementation phase. The author discusses the costs that are associated with integrating technology, as well as the hardware components and configuration. He then discusses in greater detail the core clinical technologies and how they tie in together to facilitate building a cohesive digital patient record. CONCLUSIONS: There are no shortcuts to successfully integrating technology into a dental practice. A significant commitment of time, energy and money is a prerequisite to building a secure and reliable computer network that incorporates all clinical and administrative applications. PRACTICE IMPLICATIONS: Technology is reinventing the world, and dentists need to keep pace with the people they serve. These new and not-so-new technologies will enhance dental services and productivity, which ultimately will raise the bar for the standard of care in dentistry. (+info)
Quality assurance in radiotherapy. How to improve the effectiveness and completeness of an electronic patient's chart.
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A checking form was introduced in order to test the completeness of electronic and paper patient's charts in a radiotherapy department which had introduced record-and-verify system (RVS) and to improve tha staff performance. The chosen items for the electronic chart were 9 and 5 for paper chart. 223 patients were reviewed in two phases. The data analysis was based on a scoring method, attributing a positive score (+1) to the operator's good behaviour, a negative score (-1) to the lack of data input and a neutral score (0) to the inapplicable situation. The average global score increased from 0.4 to 0.7: in A (lowest complexity) category from 0.37 to 0.64, in B category from 0.4 to 0.89, in C category from 0.48 to 0.61. (+info)
LONI visualization environment.
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Over the past decade, the use of informatics to solve complex neuroscientific problems has increased dramatically. Many of these research endeavors involve examining large amounts of imaging, behavioral, genetic, neurobiological, and neuropsychiatric data. Superimposing, processing, visualizing, or interpreting such a complex cohort of datasets frequently becomes a challenge. We developed a new software environment that allows investigators to integrate multimodal imaging data, hierarchical brain ontology systems, on-line genetic and phylogenic databases, and 3D virtual data reconstruction models. The Laboratory of Neuro Imaging visualization environment (LONI Viz) consists of the following components: a sectional viewer for imaging data, an interactive 3D display for surface and volume rendering of imaging data, a brain ontology viewer, and an external database query system. The synchronization of all components according to stereotaxic coordinates, region name, hierarchical ontology, and genetic labels is achieved via a comprehensive BrainMapper functionality, which directly maps between position, structure name, database, and functional connectivity information. This environment is freely available, portable, and extensible, and may prove very useful for neurobiologists, neurogenetisists, brain mappers, and for other clinical, pedagogical, and research endeavors. (+info)
Digital radiography. A comparison with modern conventional imaging.
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The development of computed radiography over the past two decades has transformed radiological imaging. The radiology departments in the 21st century will look very different from those in the preceding period. In this review, the development of digital radiography is presented with a description of its various forms and a comparison with screen film radiography. (+info)
DicomWorks: software for reviewing DICOM studies and promoting low-cost teleradiology.
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DicomWorks is freeware software for reading and working on medical images [digital imaging and communication in medicine (DICOM)]. It was jointly developed by two research laboratories, with the feedback of more than 35,000 registered users throughout the world who provided information to guide its development. We detail their occupations (50% radiologists, 20% engineers, 9% medical physicists, 7% cardiologists, 6% neurologists, and 8% others), geographic origins, and main interests in the software. The viewer's interface is similar to that of a picture archiving and communication system viewing station. It provides basic but efficient tools for opening DICOM images and reviewing and exporting them to teaching files or digital presentations. E-mail, FTP, or DICOM protocols are supported for transmitting images through a local network or the Internet. Thanks to its wide compatibility, a localized (15 languages) and user-friendly interface, and its opened architecture, DicomWorks helps quick development of non proprietary, low-cost image review or teleradiology solutions in developed and emerging countries. (+info)
Implementation of a local area network for nursing management.
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This paper describes the planning and implementation of a Local Area Network (LAN) for the nursing service of a 504-bed urban teaching hospital. The major goals of the network were: support for nurse executives, nurse managers, and the departmental assistants assigned to administrative offices; increased efficiency and effectiveness of the nursing administrative areas; and improved communication systems. Collaboration between the nursing service and the Computer Information Center (CIC) resulted in a network of over 70 workstations, spanning 11 buildings. The network provides access to multiple programs that support clinical, managerial, and research activities. Gateways provide access to the hospital's two mainframes. (+info)
Implementing a record-oriented clinical lab interface using HL7 version 2.1 at Indiana University Hospital.
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At the Indiana University Hospital (IUH) site on the Indianapolis campus, HL7 version 2.1 is being implemented via a TCP/IP LAN, (using the "Minimal" Lower Layer Protocol). HL7 is currently being used to convey record-oriented lab results from the local clinical laboratory system to a clinical database system via an intelligent router, which also provides store and forward capabilities. The database application displays the lab results in a variety of configurable formats to clinical users. (+info)
Implementing a complex internetwork: a case study.
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This paper concerns the implementation of a complex internetwork in late 1989 through early 1990. The purpose is to discuss the methods and approaches employed. The context is that as technology improves and computer science advances, the same problems are re-solved over and over for slightly different environments. The perspective is that the methods and approaches will remain viable while the hardware and software changes. (+info)