Jump to content

Health informatics

From Wikipedia, the free encyclopedia
(Redirected from Pharmacy informatics)

Brain imaging informatics BoneXpert software for assisting physicians
Imaging Informatics Computer-based telemedicine devices in operating room
Decision-making information systems in healthcare Neuroinformatics in healthcare

Medical informatics introduces information processing concepts and machinery to the domain of medicine.

Health informatics combines communications, information technology (IT), and health care to enhance patient care and is at the forefront of the medical technological revolution.[1]. It can be viewed as a branch of engineering and applied science.

The health domain provides an extremely wide variety of problems that can be tackled using computational techniques.[2]

Health informatics is a spectrum of multidisciplinary fields that includes study of the design, development, and application of computational innovations to improve health care.[3] The disciplines involved combine healthcare fields with computing fields, in particular computer engineering, software engineering, information engineering, bioinformatics, bio-inspired computing, theoretical computer science, information systems, data science, information technology, autonomic computing, and behavior informatics.[4]

In the healthcare industry, health informatics has provided such technological solutions as telemedicine, surgical robots, electronic health records (EHR), Picture Archiving and Communication Systems (PACS), and decision support, artificial intelligence, and machine learning innovations including IBM's Watson and Google's DeepMind platform.

In academic institutions, health informatics includes research focuses on applications of artificial intelligence in healthcare and designing medical devices based on embedded systems.[2] In some countries the term informatics is also used in the context of applying library science to data management in hospitals where it aims to develop methods and technologies for the acquisition, processing, and study of patient data,[5] An umbrella term of biomedical informatics has been proposed.[6]

Subject areas

[edit]
An example of an application of informatics in medicine is bioimage informatics.

Jan van Bemmel has described medical informatics as the theoretical and practical aspects of information processing and communication based on knowledge and experience derived from processes in medicine and health care.[2]

An example of how image processing can be applied to radiography.
An example of how the 2D Fourier transform can be used to remove unwanted information from an X-ray scan

The Faculty of Clinical Informatics has identified six high level domains of core competency for clinical informaticians:[7]

  • Health and Wellbeing in Practice
  • Information Technologies and Systems
  • Working with Data and Analytical Methods
  • Enabling Human and Organizational Change
  • Decision Making
  • Leading Informatics Teams and projects.

Tools to support practitioners

[edit]

Clinical informaticians use their knowledge of patient care combined with their understanding of informatics concepts, methods, and health informatics tools to:

  • Assess information and knowledge needs of health care professionals, patients and their families.
  • Characterize, evaluate, and refine clinical processes,
  • Develop, implement, and refine clinical decision support systems, and
  • Lead or participate in the procurement, customization, development, implementation, management, evaluation, and continuous improvement of clinical information systems.

Clinicians collaborate with other health care and information technology professionals to develop health informatics tools which promote patient care that is safe, efficient, effective, timely, patient-centered, and equitable. Many clinical informaticists are also computer scientists.

Telehealth and telemedicine

[edit]
Telemedicine system. Federal Center of Neurosurgery in Tyumen, 2013

Telehealth is the distribution of health-related services and information via electronic information and telecommunication technologies. It allows long-distance patient and clinician contact, care, advice, reminders, education, intervention, monitoring, and remote admissions. Telemedicine is sometimes used as a synonym, or is used in a more limited sense to describe remote clinical services, such as diagnosis and monitoring. Remote monitoring, also known as self-monitoring or testing, enables medical professionals to monitor a patient remotely using various technological devices. This method is primarily used for managing chronic diseases or specific conditions, such as heart disease, diabetes mellitus, or asthma.

These services can provide comparable health outcomes to traditional in-person patient encounters, supply greater satisfaction to patients, and may be cost-effective.[8] Telerehabilitation (or e-rehabilitation[40][41]) is the delivery of rehabilitation services over telecommunication networks and the Internet. Most types of services fall into two categories: clinical assessment (the patient's functional abilities in his or her environment), and clinical therapy. Some fields of rehabilitation practice that have explored telerehabilitation are: neuropsychology, speech-language pathology, audiology, occupational therapy, and physical therapy. Telerehabilitation can deliver therapy to people who cannot travel to a clinic because the patient has a disability or because of travel time. Telerehabilitation also allows experts in rehabilitation to engage in a clinical consultation at a distance.

Decision support, artificial intelligence and machine learning in healthcare

[edit]
X-ray of a hand, with automatic calculation of bone age by a computer software

A pioneer in the use of artificial intelligence in healthcare was American biomedical informatician Edward H. Shortliffe. This field deals with utilization of machine-learning algorithms and artificial intelligence, to emulate human cognition in the analysis, interpretation, and comprehension of complicated medical and healthcare data. Specifically, AI is the ability of computer algorithms to approximate conclusions based solely on input data. AI programs are applied to practices such as diagnosis processes, treatment protocol development, drug development, personalized medicine, and patient monitoring and care. A large part of industry focus of implementation of AI in the healthcare sector is in the clinical decision support systems.

As more data is collected, machine learning algorithms adapt and allow for more robust responses and solutions.[9] Numerous companies are exploring the possibilities of the incorporation of big data in the healthcare industry. Many companies investigate the market opportunities through the realms of "data assessment, storage, management, and analysis technologies" which are all crucial parts of the healthcare industry.[10] The following are examples of large companies that have contributed to AI algorithms for use in healthcare:

  • IBM's Watson Oncology is in development at Memorial Sloan Kettering Cancer Center and Cleveland Clinic. IBM is also working with CVS Health on AI applications in chronic disease treatment and with Johnson & Johnson on analysis of scientific papers to find new connections for drug development. In May 2017, IBM and Rensselaer Polytechnic Institute began a joint project entitled Health Empowerment by Analytics, Learning and Semantics (HEALS), to explore using AI technology to enhance healthcare.
  • Microsoft's Hanover project, in partnership with Oregon Health & Science University's Knight Cancer Institute, analyzes medical research to predict the most effective cancer drug treatment options for patients. Other projects include medical image analysis of tumor progression and the development of programmable cells.[11]
  • Google's DeepMind platform is being used by the UK National Health Service to detect certain health risks through data collected via a mobile app. A second project with the NHS involves analysis of medical images collected from NHS patients to develop computer vision algorithms to detect cancerous tissues.
  • Tencent is working on several medical systems and services. These include AI Medical Innovation System (AIMIS), an AI-powered diagnostic medical imaging service; WeChat Intelligent Healthcare; and Tencent Doctorwork.
  • Intel's venture capital arm Intel Capital recently invested in startup Lumiata which uses AI to identify at-risk patients and develop care options.
  • Kheiron Medical developed deep learning software to detect breast cancers in mammograms.
  • Fractal Analytics has incubated Qure.ai which focuses on using deep learning and AI to improve radiology and speed up the analysis of diagnostic x-rays.
  • Elon Musk premiering the surgical robot that implants the Neuralink brain chip
    Neuralink has come up with a next generation neuroprosthetic which intricately interfaces with thousands of neural pathways in the brain.[9] Their process allows a chip, roughly the size of a quarter, to be inserted in place of a chunk of skull by a precision surgical robot to avoid accidental injury.[9]

Digital consultant apps like Babylon Health's GP at Hand, Ada Health, Alibaba Health Doctor You, KareXpert and Your.MD use AI to give medical consultation based on personal medical history and common medical knowledge. Users report their symptoms into the app, which uses speech recognition to compare against a database of illnesses. Babylon then offers a recommended action, taking into account the user's medical history. Entrepreneurs in healthcare have been effectively using seven business model archetypes to take AI solution[buzzword] to the marketplace. These archetypes depend on the value generated for the target user (e.g. patient focus vs. healthcare provider and payer focus) and value capturing mechanisms (e.g. providing information or connecting stakeholders). IFlytek launched a service robot "Xiao Man", which integrated artificial intelligence technology to identify the registered customer and provide personalized recommendations in medical areas.

It also works in the field of medical imaging. Similar robots are also being made by companies such as UBTECH ("Cruzr") and Softbank Robotics ("Pepper"). The Indian startup Haptik recently developed a WhatsApp chatbot which answers questions associated with the deadly coronavirus in India. With the market for AI expanding constantly, large tech companies such as Apple, Google, Amazon, and Baidu all have their own AI research divisions, as well as millions of dollars allocated for acquisition of smaller AI based companies.[10] Many automobile manufacturers are beginning to use machine learning healthcare in their cars as well.[10] Companies such as BMW, GE, Tesla, Toyota, and Volvo all have new research campaigns to find ways of learning a driver's vital statistics to ensure they are awake, paying attention to the road, and not under the influence of substances or in emotional distress.[10] Examples of projects in computational health informatics include the COACH project.[12][13]

Clinical Research Informatics

[edit]

Clinical research informatics (CRI) is a sub-field of health informatics that tries to improve the efficiency of clinical research by using informatics methods. Some of the problems tackled by CRI are: creation of data warehouses of health care data that can be used for research, support of data collection in clinical trials by the use of electronic data capture systems, streamlining ethical approvals and renewals (in US the responsible entity is the local institutional review board), maintenance of repositories of past clinical trial data (de-identified). CRI is a fairly new branch of informatics and has met growing pains as any up and coming field does. Some issue CRI faces is the ability for the statisticians and the computer system architects to work with the clinical research staff in designing a system and lack of funding to support the development of a new system.

Researchers and the informatics team have a difficult time coordinating plans and ideas in order to design a system that is easy to use for the research team yet fits in the system requirements of the computer team. The lack of funding can be a hindrance to the development of the CRI. Many organizations who are performing research are struggling to get financial support to conduct the research, much less invest that money in an informatics system that will not provide them any more income or improve the outcome of the research (Embi, 2009). Ability to integrate data from multiple clinical trials is an important part of clinical research informatics. Initiatives, such as PhenX and Patient-Reported Outcomes Measurement Information System triggered a general effort to improve secondary use of data collected in past human clinical trials. CDE initiatives, for example, try to allow clinical trial designers to adopt standardized research instruments (electronic case report forms).[14]

A parallel effort to standardizing how data is collected are initiatives that offer de-identified patient level clinical study data to be downloaded by researchers who wish to re-use this data. Examples of such platforms are Project Data Sphere,[15] dbGaP, ImmPort[16] or Clinical Study Data Request.[17] Informatics issues in data formats for sharing results (plain CSV files, FDA endorsed formats, such as CDISC Study Data Tabulation Model) are important challenges within the field of clinical research informatics. There are a number of activities within clinical research that CRI supports, including:

  • More efficient and effective data collection and acquisition
  • Improved recruitment into clinical trials
  • Optimal protocol design and efficient management
  • Patient recruitment and management
  • Adverse event reporting
  • Regulatory compliance
  • Data storage, transfer,[18] processing and analysis
  • Repositories of data from completed clinical trials (for secondary analyses)
Example IDR schema

One of the fundamental elements of biomedical and translation research is the use of integrated data repositories. A survey conducted in 2010 defined "integrated data repository" (IDR) as a data warehouse incorporating various sources of clinical data to support queries for a range of research-like functions.[19] Integrated data repositories are complex systems developed to solve a variety of problems ranging from identity management, protection of confidentiality, semantic and syntactic comparability of data from different sources, and most importantly convenient and flexible query.[20]

Development of the field of clinical informatics led to the creation of large data sets with electronic health record data integrated with other data (such as genomic data). Types of data repositories include operational data stores (ODSs), clinical data warehouses (CDWs), clinical data marts, and clinical registries.[21] Operational data stores established for extracting, transferring and loading before creating warehouse or data marts.[21] Clinical registries repositories have long been in existence, but their contents are disease specific and sometimes considered archaic.[21] Clinical data stores and clinical data warehouses are considered fast and reliable. Though these large integrated repositories have impacted clinical research significantly, it still faces challenges and barriers.

One big problem is the requirement for ethical approval by the institutional review board (IRB) for each research analysis meant for publication.[22] Some research resources do not require IRB approval. For example, CDWs with data of deceased patients have been de-identified and IRB approval is not required for their usage.[22][19][21][20] Another challenge is data quality. Methods that adjust for bias (such as using propensity score matching methods) assume that a complete health record is captured. Tools that examine data quality (e.g., point to missing data) help in discovering data quality problems.[23]

Translational bioinformatics

[edit]

Translational Bioinformatics (TBI) is a relatively new field that surfaced in the year of 2000 when human genome sequence was released.[24] The commonly used definition of TBI is lengthy and could be found on the AMIA website.[25] In simpler terms, TBI could be defined as a collection of colossal amounts of health related data (biomedical and genomic) and translation of the data into individually tailored clinical entities.[24] Today, TBI field is categorized into four major themes that are briefly described below:

  • Clinical big data is a collection of electronic health records that are used for innovations. The evidence-based approach that is currently practiced in medicine is suggested to be merged with the practice-based medicine to achieve better outcomes for patients. As CEO of California-based cognitive computing firm Apixio, Darren Schutle, explains that the care can be better fitted to the patient if the data could be collected from various medical records, merged, and analyzed. Further, the combination of similar profiles can serve as a basis for personalized medicine pointing to what works and what does not for certain condition (Marr, 2016).
  • Genomics in clinical care
    Genomic data are used to identify the genes involvement in unknown or rare conditions/syndromes. Currently, the most vigorous area of using genomics is oncology. The identification of genomic sequencing of cancer may define reasons of drug(s) sensitivity and resistance during oncological treatment processes.[24]
  • Omics for drugs discovery and repurposing
    Repurposing of the drug is an appealing idea that allows the pharmaceutical companies to sell an already approved drug to treat a different condition/disease that the drug was not initially approved for by the FDA. The observation of "molecular signatures in disease and compare those to signatures observed in cells" points to the possibility of a drug ability to cure and/or relieve symptoms of a disease.[24]
  • Personalized genomic testing
    In the US, several companies offer direct-to-consumer (DTC) genetic testing. The company that performs the majority of testing is called 23andMe. Utilizing genetic testing in health care raises many ethical, legal and social concerns; one of the main questions is whether the health care providers are ready to include patient-supplied genomic information while providing care that is unbiased (despite the intimate genomic knowledge) and a high quality. The documented examples of incorporating such information into a health care delivery showed both positive and negative impacts on the overall health care related outcomes.[24]

Medical signal processing

[edit]

An important application of information engineering in medicine is medical signal processing.[2] It refers to the generation, analysis, and use of signals, which could take many forms such as image, sound, electrical, or biological.[26]

Medical image computing and imaging informatics

[edit]
A mid-axial slice of the ICBM diffusion tensor image template. Each voxel's value is a tensor represented here by an ellipsoid. Color denotes principal orientation: red = left-right, blue=inferior-superior, green = posterior-anterior

Imaging informatics and medical image computing develops computational and mathematical methods for solving problems pertaining to medical images and their use for biomedical research and clinical care. Those fields aims to extract clinically relevant information or knowledge from medical images and computational analysis of the images. The methods can be grouped into several broad categories: image segmentation, image registration, image-based physiological modeling, and others.

Medical robotics

[edit]

A medical robot is a robot used in the medical sciences. They include surgical robots. These are in most telemanipulators, which use the surgeon's activators on one side to control the "effector" on the other side. There are the following types of medical robots:

  • Surgical robots: either allow surgical operations to be carried out with better precision than an unaided human surgeon or allow remote surgery where a human surgeon is not physically present with the patient.
  • Rehabilitation robots: facilitate and support the lives of infirm, elderly people, or those with dysfunction of body parts affecting movement. These robots are also used for rehabilitation and related procedures, such as training and therapy.
  • Biorobots: a group of robots designed to imitate the cognition of humans and animals.
  • Telepresence robots: allow off-site medical professionals to move, look around, communicate, and participate from remote locations.[27]
  • Pharmacy automation: robotic systems to dispense oral solids in a retail pharmacy setting or preparing sterile IV admixtures in a hospital pharmacy setting.
  • Companion robot: has the capability to engage emotionally with users keeping them company and alerting if there is a problem with their health.
  • Disinfection robot: has the capability to disinfect a whole room in mere minutes, generally using pulsed ultraviolet light.[28][29] They are being used to fight Ebola virus disease.[30]

Pathology informatics

[edit]
Major topics and processes of pathology informatics: Data management from molecular testing, slide scanning, digital imaging and image analysis, networks, databases and telepathology.

Pathology informatics is a field that involves the use of information technology, computer systems, and data management to support and enhance the practice of pathology. It encompasses pathology laboratory operations, data analysis, and the interpretation of pathology-related information.

Key aspects of pathology informatics include:

  • Laboratory information management systems (LIMS): Implementing and managing computer systems specifically designed for pathology departments. These systems help in tracking and managing patient specimens, results, and other pathology data.
  • Digital pathology: Involves the use of digital technology to create, manage, and analyze pathology images. This includes side scanning and automated image analysis.
  • Telepathology: Using technology to enable remote pathology consultation and collaboration.
  • Quality assurance and reporting: Implementing informatics solutions to ensure the quality and accuracy of pathology processes.

International history

[edit]

Worldwide use of computer technology in medicine began in the early 1950s with the rise of the computers. In 1949, Gustav Wagner established the first professional organization for informatics in Germany. Specialized university departments and Informatics training programs began during the 1960s in France, Germany, Belgium and The Netherlands. Medical informatics research units began to appear during the 1970s in Poland and in the U.S.[31] Since then the development of high-quality health informatics research, education and infrastructure has been a goal of the U.S. and the European Union.

Early names for health informatics included medical computing, biomedical computing, medical computer science, computer medicine, medical electronic data processing, medical automatic data processing, medical information processing, medical information science, medical software engineering, and medical computer technology.

The health informatics community is still growing, it is by no means a mature profession, but work in the UK by the voluntary registration body, the UK Council of Health Informatics Professions has suggested eight key constituencies within the domain–information management, knowledge management, portfolio/program/project management, ICT, education and research, clinical informatics, health records(service and business-related), health informatics service management. These constituencies accommodate professionals in and for the NHS, in academia and commercial service and solution providers.

Since the 1970s the most prominent international coordinating body has been the International Medical Informatics Association (IMIA).

History, current state and policy initiatives by region and country

[edit]

Americas

[edit]

Argentina

[edit]

The Argentinian health system is heterogeneous in its function, and because of that, the informatics developments show a heterogeneous stage. Many private health care centers have developed systems, such as the Hospital Aleman of Buenos Aires, or the Hospital Italiano de Buenos Aires that also has a residence program for health informatics.[citation needed]

Brazil

[edit]

The first applications of computers to medicine and health care in Brazil started around 1968, with the installation of the first mainframes in public university hospitals, and the use of programmable calculators in scientific research applications. Minicomputers, such as the IBM 1130 were installed in several universities, and the first applications were developed for them, such as the hospital census in the School of Medicine of Ribeirão Preto and patient master files, in the Hospital das Clínicas da Universidade de São Paulo, respectively at the cities of Ribeirão Preto and São Paulo campuses of the University of São Paulo.

In the 1970s, several Digital Corporation and Hewlett-Packard minicomputers were acquired for public and Armed Forces hospitals, and more intensively used for intensive-care unit, cardiology diagnostics, patient monitoring and other applications. In the early 1980s, with the arrival of cheaper microcomputers, a great upsurge of computer applications in health ensued, and in 1986 the Brazilian Society of Health Informatics was founded, the first Brazilian Congress of Health Informatics was held, and the first Brazilian Journal of Health Informatics was published. In Brazil, two universities are pioneers in teaching and research in medical informatics, both the University of São Paulo and the Federal University of São Paulo offer undergraduate programs highly qualified in the area as well as extensive graduate programs (MSc and PhD). In 2015 the Universidade Federal de Ciências da Saúde de Porto Alegre, Rio Grande do Sul, also started to offer undergraduate program.

Canada

[edit]

Health Informatics projects in Canada are implemented provincially, with different provinces creating different systems. A national, federally funded, not-for-profit organisation called Canada Health Infoway was created in 2001 to foster the development and adoption of electronic health records across Canada. As of December 31, 2008, there were 276 EHR projects under way in Canadian hospitals, other health-care facilities, pharmacies and laboratories, with an investment value of $1.5-billion from Canada Health Infoway.[32]

Provincial and territorial programmes include the following:

  • eHealth Ontario was created as an Ontario provincial government agency in September 2008. It has been plagued by delays and its CEO was fired over a multimillion-dollar contracts scandal in 2009.[33]
  • Alberta Netcare was created in 2003 by the Government of Alberta. Today the netCARE portal is used daily by thousands of clinicians. It provides access to demographic data, prescribed/dispensed drugs, known allergies/intolerances, immunizations, laboratory test results, diagnostic imaging reports, the diabetes registry and other medical reports. netCARE interface capabilities are being included in electronic medical record products that are being funded by the provincial government.

United States

[edit]

Even though the idea of using computers in medicine emerged as technology advanced in the early 20th century, it was not until the 1950s that informatics began to have an effect in the United States.[34]

The earliest use of electronic digital computers for medicine was for dental projects in the 1950s at the United States National Bureau of Standards by Robert Ledley.[35] During the mid-1950s, the United States Air Force (USAF) carried out several medical projects on its computers while also encouraging civilian agencies such as the National Academy of Sciences – National Research Council (NAS-NRC) and the National Institutes of Health (NIH) to sponsor such work.[36] In 1959, Ledley and Lee B. Lusted published "Reasoning Foundations of Medical Diagnosis," a widely read article in Science, which introduced computing (especially operations research) techniques to medical workers. Ledley and Lusted's article has remained influential for decades, especially within the field of medical decision making.[37]

Guided by Ledley's late 1950s survey of computer use in biology and medicine (carried out for the NAS-NRC), and by his and Lusted's articles, the NIH undertook the first major effort to introduce computers to biology and medicine. This effort, carried out initially by the NIH's Advisory Committee on Computers in Research (ACCR), chaired by Lusted, spent over $40 million between 1960 and 1964 in order to establish dozens of large and small biomedical research centers in the US.[36]

One early (1960, non-ACCR) use of computers was to help quantify normal human movement, as a precursor to scientifically measuring deviations from normal, and design of prostheses.[38] The use of computers (IBM 650, 1620, and 7040) allowed analysis of a large sample size, and of more measurements and subgroups than had been previously practical with mechanical calculators, thus allowing an objective understanding of how human locomotion varies by age and body characteristics. A study co-author was Dean of the Marquette University College of Engineering; this work led to discrete Biomedical Engineering departments there and elsewhere.

The next steps, in the mid-1960s, were the development (sponsored largely by the NIH) of expert systems such as MYCIN and Internist-I. In 1965, the National Library of Medicine started to use MEDLINE and MEDLARS. Around this time, Neil Pappalardo, Curtis Marble, and Robert Greenes developed MUMPS (Massachusetts General Hospital Utility Multi-Programming System) in Octo Barnett's Laboratory of Computer Science[39] at Massachusetts General Hospital in Boston, another center of biomedical computing that received significant support from the NIH.[40] In the 1970s and 1980s it was the most commonly used programming language for clinical applications. The MUMPS operating system was used to support MUMPS language specifications. As of 2004, a descendant of this system is being used in the United States Veterans Affairs hospital system. The VA has the largest enterprise-wide health information system that includes an electronic medical record, known as the Veterans Health Information Systems and Technology Architecture (VistA). A graphical user interface known as the Computerized Patient Record System (CPRS) allows health care providers to review and update a patient's electronic medical record at any of the VA's over 1,000 health care facilities.

During the 1960s, Morris F. Collen, a physician working for Kaiser Permanente's Division of Research, developed computerized systems to automate many aspects of multi-phased health checkups. These systems became the basis the larger medical databases Kaiser Permanente developed during the 1970s and 1980s.[41] The American Medical Informatics Association presents the Morris F. Collen Award of Excellence for an individual's lifetime achievement in biomedical informatics.

In the 1970s a growing number of commercial vendors began to market practice management and electronic medical records systems. Although many products exist, only a small number of health practitioners use fully featured electronic health care records systems. In 1970, Warner V. Slack, MD, and Howard Bleich, MD, co-founded[42] the academic division of clinical informatics (DCI)[43] at Beth Israel Deaconess Medical Center and Harvard Medical School. Warner Slack is a pioneer of the development of the electronic patient medical history,[44] and in 1977 Dr. Bleich created the first user-friendly search engine for the worlds biomedical literature.[45][46]

Computerised systems involved in patient care have led to a number of changes. Such changes have led to improvements in electronic health records which are now capable of sharing medical information among multiple health care stakeholders (Zahabi, Kaber, & Swangnetr, 2015); thereby, supporting the flow of patient information through various modalities of care. One opportunity for electronic health records (EHR) to be even more effectively used is to utilize natural language processing for searching and analyzing notes and text that would otherwise be inaccessible for review. These can be further developed through ongoing collaboration between software developers and end-users of natural language processing tools within the electronic health EHRs.[47]

Computer use today involves a broad ability which includes but is not limited to physician diagnosis and documentation, patient appointment scheduling, and billing. Many researchers in the field have identified an increase in the quality of health care systems, decreased errors by health care workers, and lastly savings in time and money (Zahabi, Kaber, & Swangnetr, 2015). The system, however, is not perfect and will continue to require improvement. Frequently cited factors of concern involve usability, safety, accessibility, and user-friendliness (Zahabi, Kaber, & Swangnetr, 2015).[48]

Homer R. Warner, one of the fathers of medical informatics,[49] founded the Department of Medical Informatics at the University of Utah in 1968. The American Medical Informatics Association (AMIA) has an award named after him on application of informatics to medicine.

The American Medical Informatics Association created a,[50] board certification for medical informatics from the American Board of Preventive Medicine.[51] The American Nurses Credentialing Center offers a board certification in Nursing Informatics.[52] For Radiology Informatics, the CIIP (Certified Imaging Informatics Professional) certification was created by ABII (The American Board of Imaging Informatics) which was founded by SIIM (the Society for Imaging Informatics in Medicine) and ARRT (the American Registry of Radiologic Technologists) in 2005. The CIIP certification requires documented experience working in Imaging Informatics, formal testing and is a limited time credential requiring renewal every five years.

The exam tests for a combination of IT technical knowledge, clinical understanding, and project management experience thought to represent the typical workload of a PACS administrator or other radiology IT clinical support role.[53] Certifications from PARCA (PACS Administrators Registry and Certifications Association) are also recognized. The five PARCA certifications are tiered from entry-level to architect level. The American Health Information Management Association offers credentials in medical coding, analytics, and data administration, such as Registered Health Information Administrator and Certified Coding Associate.[54] Certifications are widely requested by employers in health informatics, and overall the demand for certified informatics workers in the United States is outstripping supply.[55] The American Health Information Management Association reports that only 68% of applicants pass certification exams on the first try.[56]

In 2017, a consortium of health informatics trainers (composed of MEASURE Evaluation, Public Health Foundation India, University of Pretoria, Kenyatta University, and the University of Ghana) identified the following areas of knowledge as a curriculum for the digital health workforce, especially in low- and middle-income countries: clinical decision support; telehealth; privacy, security, and confidentiality; workflow process improvement; technology, people, and processes; process engineering; quality process improvement and health information technology; computer hardware; software; databases; data warehousing; information networks; information systems; information exchange; data analytics; and usability methods.[57]

In 2004, President George W. Bush signed Executive Order 13335,[58] creating the Office of the National Coordinator for Health Information Technology (ONCHIT) as a division of the U.S. Department of Health and Human Services (HHS). The mission of this office is widespread adoption of interoperable electronic health records (EHRs) in the US within 10 years. See quality improvement organizations for more information on federal initiatives in this area. In 2014 the Department of Education approved an advanced Health Informatics Undergraduate program that was submitted by the University of South Alabama. The program is designed to provide specific Health Informatics education, and is the only program in the country with a Health Informatics Lab. The program is housed in the School of Computing in Shelby Hall, a recently completed $50 million state of the art teaching facility. The University of South Alabama awarded David L. Loeser on May 10, 2014, with the first Health Informatics degree.

The program currently is scheduled to have 100+ students awarded by 2016. The Certification Commission for Healthcare Information Technology (CCHIT), a private nonprofit group, was funded in 2005 by the U.S. Department of Health and Human Services to develop a set of standards for electronic health records (EHR) and supporting networks, and certify vendors who meet them. In July 2006, CCHIT released its first list of 22 certified ambulatory EHR products, in two different announcements.[59] Harvard Medical School added a department of biomedical informatics in 2015.[60] The University of Cincinnati in partnership with Cincinnati Children's Hospital Medical Center created a biomedical informatics (BMI) Graduate certificate program and in 2015 began a BMI PhD program.[61][62][63] The joint program allows for researchers and students to observe the impact their work has on patient care directly as discoveries are translated from bench to bedside. The University of California, San Diego with support from the National Center for Advancing Translational Sciences provides training programs in biomedical inforamtics through Doctor of Philosophy and post-doctoral fellowship programs,[64] including a course specifically in health informatics taught by the cancer informaticist Raphael E. Cuomo.[65][66]

Europe

[edit]

European Union

[edit]

The European Commission's preference, as exemplified in the 5th Framework[67] as well as currently pursued pilot projects,[68] is for Free/Libre and Open Source Software (FLOSS) for health care.

The European Union's Member States are committed to sharing their best practices and experiences to create a European eHealth Area, thereby improving access to and quality health care at the same time as stimulating growth in a promising new industrial sector. The European eHealth Action Plan plays a fundamental role in the European Union's strategy. Work on this initiative involves a collaborative approach among several parts of the Commission services.[69][70] The European Institute for Health Records is involved in the promotion of high quality electronic health record systems in the European Union.[71]

UK

[edit]

The broad history of health informatics has been captured in the book UK Health Computing: Recollections and reflections, Hayes G, Barnett D (Eds.), BCS (May 2008) by those active in the field, predominantly members of BCS Health and its constituent groups. The book describes the path taken as "early development of health informatics was unorganized and idiosyncratic". In the early 1950s, it was prompted by those involved in NHS finance and only in the early 1960s did solutions including those in pathology (1960), radiotherapy (1962), immunization (1963), and primary care (1968) emerge. Many of these solutions, even in the early 1970s were developed in-house by pioneers in the field to meet their own requirements. In part, this was due to some areas of health services (for example the immunization and vaccination of children) still being provided by Local Authorities.

The coalition government has proposed broadly to return to the 2010 strategy Equity and Excellence: Liberating the NHS (July 2010); stating: "We will put patients at the heart of the NHS, through an information revolution and greater choice and control' with shared decision-making becoming the norm: "no decision about me without me' and patients having access to the information they want, to make choices about their care. They will have increased control over their own care records."[citation needed]

There are different models of health informatics delivery in each of the home countries (England, Scotland, Northern Ireland and Wales) but some bodies like UKCHIP[72] (see below) operate for those 'in and for' all the home countries and beyond.

NHS informatics in England was contracted out to several vendors for national health informatics solutions under the National Programme for Information Technology (NPfIT) label in the early to mid-2000s, under the auspices of NHS Connecting for Health (part of the Health and Social Care Information Centre as of 1 April 2013). NPfIT originally divided the country into five regions, with strategic 'systems integration' contracts awarded to one of several Local Service Providers (LSP).

The various specific technical solutions were required to connect securely with the NHS 'Spine', a system designed to broker data between different systems and care settings. NPfIT fell significantly behind schedule and its scope and design were being revised in real time, exacerbated by media and political lambasting of the Programme's spend (past and projected) against the proposed budget. In 2010 a consultation was launched as part of the new Conservative/Liberal Democrat Coalition Government's White Paper "Liberating the NHS". This initiative provided little in the way of innovative thinking, primarily re-stating existing strategies within the proposed new context of the Coalition's vision for the NHS. The degree of computerization in NHS secondary care was quite high before NPfIT, and the programme stagnated further development of the install base – the original NPfIT regional approach provided neither a single, nationwide solution nor local health community agility or autonomy to purchase systems, but instead tried to deal with a hinterland in the middle.

Almost all general practices in England and Wales are computerized under the GP Systems of Choice[73] programme, and patients have relatively extensive computerized primary care clinical records. System choice is the responsibility of individual general practices and while there is no single, standardized GP system, it sets relatively rigid minimum standards of performance and functionality for vendors to adhere to. Interoperation between primary and secondary care systems is rather primitive. It is hoped that a focus on interworking (for interfacing and integration) standards will stimulate synergy between primary and secondary care in sharing necessary information to support the care of individuals. Notable successes to date are in the electronic requesting and viewing of test results, and in some areas, GPs have access to digital x-ray images from secondary care systems.

In 2019 the GP Systems of Choice framework was replaced by the GP IT Futures framework, which is to be the main vehicle used by clinical commissioning groups to buy services for GPs. This is intended to increase competition in an area that is dominated by EMIS and TPP. 69 technology companies offering more than 300 solutions have been accepted on to the new framework.[74]

Wales has a dedicated Health Informatics function that supports NHS Wales in leading on the new integrated digital information services and promoting Health Informatics as a career.

The British Computer Society (BCS) [75] provides 4 different professional registration levels for Health and Care Informatics Professionals: Practitioner, Senior Practitioner, Advanced Practitioner, and Leading Practitioner. The Faculty of Clinical Informatics (FCI) [76] is the professional membership society for health and social care professionals in clinical informatics offering Fellowship, Membership and Associateship. BCS and FCI are member organizations of the Federation for Informatics Professionals in Health and Social Care (FedIP),[77] a collaboration between the leading professional bodies in health and care informatics supporting the development of the informatics professions.

The Faculty of Clinical Informatics has produced a Core Competency Framework that describes the wide range of skills needed by practitioners.[78]

Netherlands

[edit]

In the Netherlands, health informatics is currently a priority for research and implementation. The Netherlands Federation of University medical centers (NFU)[79] has created the Citrienfonds, which includes the programs eHealth and Registration at the Source.[80] The Netherlands also has the national organizations Society for Healthcare Informatics (VMBI)[81] and Nictiz, the national center for standardization and eHealth.[82]

Asia and Oceania

[edit]

In Asia and Australia-New Zealand, the regional group called the Asia Pacific Association for Medical Informatics (APAMI)[83] was established in 1994 and now consists of more than 15 member regions in the Asia Pacific Region.

Australia

[edit]

The Australasian College of Health Informatics (ACHI) is the professional association for health informatics in the Asia-Pacific region. It represents the interests of a broad range of clinical and non-clinical professionals working within the health informatics sphere through a commitment to quality, standards and ethical practice.[84] ACHI is an academic institutional member of the International Medical Informatics Association (IMIA)[85] and a full member of the Australian Council of Professions.[86] ACHI is a sponsor of the "e-Journal for Health Informatics",[87] an indexed and peer-reviewed professional journal. ACHI has also supported the "Australian Health Informatics Education Council" (AHIEC) since its founding in 2009.[88]

Although there are a number of health informatics organizations in Australia, the Health Informatics Society of Australia[89] (HISA) is regarded as the major umbrella group and is a member of the International Medical Informatics Association (IMIA). Nursing informaticians were the driving force behind the formation of HISA, which is now a company limited by guarantee of the members. The membership comes from across the informatics spectrum that is from students to corporate affiliates. HISA has a number of branches (Queensland, New South Wales, Victoria and Western Australia) as well as special interest groups such as nursing (NIA), pathology, aged and community care, industry and medical imaging (Conrick, 2006).

China

[edit]

After 20 years, China performed a successful transition from its planned economy to a socialist market economy. Along this change, China's health care system also experienced a significant reform to follow and adapt to this historical revolution. In 2003, the data (released from Ministry of Health of the People's Republic of China (MoH)), indicated that the national health care-involved expenditure was up to RMB 662.33 billion totally, which accounted for about 5.56% of nationwide gross domestic products. Before the 1980s, the entire health care costs were covered in central government annual budget. Since that, the construct of health care-expended supporters started to change gradually. Most of the expenditure was contributed by health insurance schemes and private spending, which corresponded to 40% and 45% of total expenditure, respectively. Meanwhile, the financially governmental contribution was decreased to 10% only. On the other hand, by 2004, up to 296,492 health care facilities were recorded in statistic summary of MoH, and an average of 2.4 clinical beds per 1000 people were mentioned as well.[90]

Proportion of nationwide hospitals with HIS in China by 2004

Along with the development of information technology since the 1990s, health care providers realized that the information could generate significant benefits to improve their services by computerized cases and data, for instance of gaining the information for directing patient care and assessing the best patient care for specific clinical conditions. Therefore, substantial resources were collected to build China's own health informatics system.

Most of these resources were arranged to construct hospital information system (HIS), which was aimed to minimize unnecessary waste and repetition, subsequently to promote the efficiency and quality-control of health care.[91] By 2004, China had successfully spread HIS through approximately 35–40% of nationwide hospitals.[92] However, the dispersion of hospital-owned HIS varies critically. In the east part of China, over 80% of hospitals constructed HIS, in northwest of China the equivalent was no more than 20%. Moreover, all of the Centers for Disease Control and Prevention (CDC) above rural level, approximately 80% of health care organisations above the rural level and 27% of hospitals over town level have the ability to perform the transmission of reports about real-time epidemic situation through public health information system and to analysis infectious diseases by dynamic statistics.[93]

China has four tiers in its health care system. The first tier is street health and workplace clinics and these are cheaper than hospitals in terms of medical billing and act as prevention centers. The second tier is district and enterprise hospitals along with specialist clinics and these provide the second level of care. The third tier is provisional and municipal general hospitals and teaching hospitals which provided the third level of care. In a tier of its own is the national hospitals which are governed by the Ministry of Health. China has been greatly improving its health informatics since it finally opened its doors to the outside world and joined the World Trade Organization (WTO). In 2001, it was reported that China had 324,380 medical institutions and the majority of those were clinics. The reason for that is that clinics are prevention centers and Chinese people like using traditional Chinese medicine as opposed to Western medicine and it usually works for the minor cases. China has also been improving its higher education in regards to health informatics.

At the end of 2002, there were 77 medical universities and medical colleges. There were 48 university medical colleges which offered bachelor, master, and doctorate degrees in medicine. There were 21 higher medical specialty institutions that offered diploma degrees so in total, there were 147 higher medical and educational institutions. Since joining the WTO, China has been working hard to improve its education system and bring it up to international standards.[94] SARS played a large role in China quickly improving its health care system. Back in 2003, there was an outbreak of SARS and that made China hurry to spread HIS or Hospital Information System and more than 80% of hospitals had HIS. China had been comparing itself to Korea's health care system and figuring out how it can better its own system. There was a study done that surveyed six hospitals in China that had HIS. The results were that doctors did not use computers as much so it was concluded that it was not used as much for clinical practice than it was for administrative purposes. The survey asked if the hospitals created any websites and it was concluded that only four of them had created websites and that three had a third-party company create it for them and one was created by the hospital staff. In conclusion, all of them agreed or strongly agreed that providing health information on the Internet should be utilized.[95]

Collected information at different times, by different participants or systems could frequently lead to issues of misunderstanding, dis-comparing or dis-exchanging. To design an issues-minor system, health care providers realized that certain standards were the basis for sharing information and interoperability, however a system lacking standards would be a large impediment to interfere the improvement of corresponding information systems. Given that the standardization for health informatics depends on the authorities, standardization events must be involved with government and the subsequently relevant funding and supports were critical. In 2003, the Ministry of Health released the Development Lay-out of National Health Informatics (2003–2010)[96] indicating the identification of standardization for health informatics which is 'combining adoption of international standards and development of national standards'.

In China, the establishment of standardization was initially facilitated with the development of vocabulary, classification and coding, which is conducive to reserve and transmit information for premium management at national level. By 2006, 55 international/ domestic standards of vocabulary, classification and coding have served in hospital information system. In 2003, the 10th revision of the International Statistical Classification of Diseases and Related Health Problems (ICD-10) and the ICD-10 Clinical Modification (ICD-10-CM) were adopted as standards for diagnostic classification and acute care procedure classification. Simultaneously, the International Classification of Primary Care (ICPC) were translated and tested in China 's local applied environment.[97] Another coding standard, named Logical Observation Identifiers Names and Codes (LOINC), was applied to serve as general identifiers for clinical observation in hospitals.

Personal identifier codes were widely employed in different information systems, involving name, sex, nationality, family relationship, educational level and job occupation. However, these codes within different systems are inconsistent, when sharing between different regions. Considering this large quantity of vocabulary, classification and coding standards between different jurisdictions, the health care provider realized that using multiple systems could generate issues of resource wasting and a non-conflicting national level standard was beneficial and necessary. Therefore, in late 2003, the health informatics group in Ministry of Health released three projects to deal with issues of lacking national health information standards, which were the Chinese National Health Information Framework and Standardization, the Basic Data Set Standards of Hospital Information System and the Basic Data Set Standards of Public Health Information System.

The objectives of the Chinese National Health Information Framework and Standardization project were:[90]

  1. Establish national health information framework and identify in what areas standards and guidelines are required
  2. Identify the classes, relationships and attributes of national health information framework. Produce a conceptual health data model to cover the scope of the health information framework
  3. Create logical data model for specific domains, depicting the logical data entities, the data attributes, and the relationships between the entities according to the conceptual health data model
  4. Establish uniform represent standard for data elements according to the data entities and their attributes in conceptual data model and logical data model
  5. Circulate the completed health information framework and health data model to the partnership members for review and acceptance
  6. Develop a process to maintain and refine the China model and to align with and influence international health data models
Comparing China's EHR Standard and ASTM E1384
[edit]

In 2011, researchers from local universities evaluated the performance of China's Electronic Health Record (EHR) Standard compared with the American Society for Testing and Materials Standard Practice for Content and Structure of Electronic Health Records in the United States (ASTM E1384 Standard, withdrawn in 2017).[98] The deficiencies that were found are listed in the following.

  1. The lack of supporting on privacy and security. The ISO/TS 18308 specifies "The EHR must support the ethical and legal use of personal information, in accordance with established privacy principles and frameworks, which may be culturally or jurisdictionally specific" (ISO 18308: Health Informatics-Requirements for an Electronic Health Record Architecture, 2004). However this China's EHR Standard did not achieve any of the fifteen requirements in the subclass of privacy and security.
  2. The shortage of supporting on different types of data and reference. Considering only ICD-9 is referenced as China's external international coding systems, other similar systems, such as SNOMED CT in clinical terminology presentation, cannot be considered as familiar for Chinese specialists, which could lead to internationally information-sharing deficiency.
  3. The lack of more generic and extensible lower level data structures. China's large and complex EHR Standard was constructed for all medical domains. However, the specific and time-frequent attributes of clinical data elements, value sets and templates identified that this once-for-all purpose cannot lead to practical consequence.[99]

In Hong Kong, a computerized patient record system called the Clinical Management System (CMS) has been developed by the Hospital Authority since 1994. This system has been deployed at all the sites of the authority (40 hospitals and 120 clinics). It is used for up to 2 million transactions daily by 30,000 clinical staff. The comprehensive records of 7 million patients are available on-line in the electronic patient record (ePR), with data integrated from all sites. Since 2004 radiology image viewing has been added to the ePR, with radiography images from any HA site being available as part of the ePR.

The Hong Kong Hospital Authority placed particular attention to the governance of clinical systems development, with input from hundreds of clinicians being incorporated through a structured process. The health informatics section in the Hospital Authority[100] has a close relationship with the information technology department and clinicians to develop health care systems for the organization to support the service to all public hospitals and clinics in the region.

The Hong Kong Society of Medical Informatics (HKSMI) was established in 1987 to promote the use of information technology in health care. The eHealth Consortium has been formed to bring together clinicians from both the private and public sectors, medical informatics professionals and the IT industry to further promote IT in health care in Hong Kong.[101]

India

[edit]
  • eHCF School of Medical Informatics[102]
  • eHealth-Care Foundation[103]

Malaysia

[edit]

Since 2010, the Ministry of Health (MoH) has been working on the Malaysian Health Data Warehouse (MyHDW) project. MyHDW aims to meet the diverse needs of timely health information provision and management, and acts as a platform for the standardization and integration of health data from a variety of sources (Health Informatics Centre, 2013). The Ministry of Health has embarked on introducing the electronic Hospital Information Systems (HIS) in several public hospitals including Putrajaya Hospital, Serdang Hospital and Selayang Hospital. Similarly, under Ministry of Higher Education, hospitals such as University of Malaya Medical Centre (UMMC) and University Kebangsaan Malaysia Medical Centre (UKMMC) are also using HIS for healthcare delivery.

A hospital information system (HIS) is a comprehensive, integrated information system designed to manage the administrative, financial and clinical aspects of a hospital. As an area of medical informatics, the aim of hospital information system is to achieve the best possible support of patient care and administration by electronic data processing. HIS plays a vital role in planning, initiating, organizing and controlling the operations of the subsystems of the hospital and thus provides a synergistic organization in the process.

New Zealand

[edit]

Health informatics is taught at five New Zealand universities. The most mature and established programme has been offered for over a decade at Otago.[104] Health Informatics New Zealand (HINZ), is the national organization that advocates for health informatics. HINZ organizes a conference every year and also publishes a journal, Healthcare Informatics Review Online.

Saudi Arabia

[edit]

The Saudi Association for Health Information (SAHI) was established in 2006[105] to work under direct supervision of King Saud bin Abdulaziz University for Health Sciences to practice public activities, develop theoretical and applicable knowledge, and provide scientific and applicable studies.[106]

Russia

[edit]

The Russian health care system is based on the principles of the Soviet health care system, which was oriented on mass prophylaxis, prevention of infection and epidemic diseases, vaccination and immunization of the population on a socially protected basis. The current government health care system consists of several directions:

  • Preventive health care
  • Primary health care
  • Specialized medical care
  • Obstetrical and gynecologic medical care
  • Pediatric medical care
  • Surgery
  • Rehabilitation/ Health resort treatment

One of the main issues of the post-Soviet medical health care system was the absence of the united system providing optimization of work for medical institutes with one, single database and structured appointment schedule and hence hours-long lines. Efficiency of medical workers might have been also doubtful because of the paperwork administrating or lost book records.

Along with the development of the information systems IT and health care departments in Moscow agreed on design of a system that would improve public services of health care institutes. Tackling the issues appearing in the existing system, the Moscow Government ordered that the design of a system would provide simplified electronic booking to public clinics and automate the work of medical workers on the first level.

The system designed for that purposes was called EMIAS (United Medical Information and Analysis System) and presents an electronic health record (EHR) with the majority of other services set in the system that manages the flow of patients, contains outpatient card integrated in the system, and provides an opportunity to manage consolidated managerial accounting and personalized list of medical help. Besides that, the system contains information about availability of the medical institutions and various doctors.

The implementation of the system started in 2013 with the organization of one computerized database for all patients in the city, including a front-end for the users. EMIAS was implemented in Moscow and the region and it is planned that the project should extend to most parts of the country.

Law

[edit]

Health informatics law deals with evolving and sometimes complex legal principles as they apply to information technology in health-related fields. It addresses the privacy, ethical and operational issues that invariably arise when electronic tools, information and media are used in health care delivery. Health Informatics Law also applies to all matters that involve information technology, health care and the interaction of information. It deals with the circumstances under which data and records are shared with other fields or areas that support and enhance patient care.

As many health care systems are making an effort to have patient records more readily available to them via the internet, it is important that providers implement security standards in order to ensure that the patients' information is safe. They have to be able to assure confidentiality, integrity, and security of the people, process, and technology. Since there is also the possibility of payments being made through this system, it is vital that this aspect of their private information will also be protected through cryptography.

The use of technology in health care settings has become popular and this trend is expected to continue. Various health care facilities had instigated different kinds of health information technology systems in the provision of patient care, such as electronic health records (EHRs), computerized charting, etc.[107] The growing popularity of health information technology systems and the escalation in the amount of health information that can be exchanged and transferred electronically increased the risk of potential infringement in patients' privacy and confidentiality.[108] This concern triggered the establishment of strict measures by both policymakers and individual facility to ensure patient privacy and confidentiality.

One of the federal laws enacted to safeguard patient's health information (medical record, billing information, treatment plan, etc.) and to guarantee patient's privacy is the Health Insurance Portability and Accountability Act of 1996 or HIPAA.[109] HIPAA gives patients the autonomy and control over their own health records.[109] Furthermore, according to the U.S. Department of Health & Human Services (n.d.), this law enables patients to:[109]

  • View their own health records
  • Request a copy of their own medical records
  • Request correction to any incorrect health information
  • Know who has access to their health record
  • Request who can and cannot view/access their health information

Health and medical informatics journals

[edit]
Impact factors of scholarly journals publishing digital health (ehealth, mhealth) work

Computers and Biomedical Research, published in 1967, was one of the first dedicated journals to health informatics. Other early journals included Computers and Medicine, published by the American Medical Association; Journal of Clinical Computing, published by Gallagher Printing; Journal of Medical Systems, published by Plenum Press; and MD Computing, published by Springer-Verlag. In 1984, Lippincott published the first nursing-specific journal, titled Journal Computers in Nursing, which is now known as Computers Informatics Nursing (CIN).[110]

As of September 7, 2016, there are roughly 235 informatics journals listed in the National Library of Medicine (NLM) catalog of journals.[111] The Journal Citation Reports for 2018 gives the top three journals in medical informatics as the Journal of Medical Internet Research (impact factor of 4.945), JMIR mHealth and uHealth (4.301) and the Journal of the American Medical Informatics Association (4.292).[112]

Competencies, education and certification

[edit]

In the United States, clinical informatics is a subspecialty within several medical specialties. For example, in pathology, the American Board of Pathology offers clinical informatics certification for pathologists who have completed 24 months of related training,[113] and the American Board of Preventive Medicine offers clinical informatics certification within preventive medicine.[114]

In October 2011 American Board of Medical Specialties (ABMS), the organization overseeing the certification of specialist MDs in the United States, announced the creation of MD-only physician certification in clinical informatics. The first examination for board certification in the subspecialty of clinical informatics was offered in October 2013 by American Board of Preventive Medicine (ABPM) with 432 passing to become the 2014 inaugural class of Diplomates in clinical informatics.[115] Fellowship programs exist for physicians who wish to become board-certified in clinical informatics. Physicians must have graduated from a medical school in the United States or Canada, or a school located elsewhere that is approved by the ABPM. In addition, they must complete a primary residency program such as Internal Medicine (or any of the 24 subspecialties recognized by the ABMS) and be eligible to become licensed to practice medicine in the state where their fellowship program is located.[116] The fellowship program is 24 months in length, with fellows dividing their time between Informatics rotations, didactic method, research, and clinical work in their primary specialty.

See also

[edit]
[edit]

Algorithms

[edit]

Governance

[edit]

References

[edit]
  1. ^ Mohd J, Abid H, Ravi P (17 December 2023). "Health informatics to enhance the healthcare industry's culture: An extensive analysis of its features, contributions, applications and limitations". Informatics and Health. 1 (2). doi:10.1016/j.infoh.2024.05.001.
  2. ^ a b c d Sami HR, Reynolds NC (7 May 2021). Talavera F, Busis NA, Lorenzo N (eds.). "Medical informatics in neurology: What Is Medical Informatics?, Signal Processing, Image Processing". EMedicine: Medscape's Continually Updated Clinical Reference.
  3. ^ Nadri H, Rahimi B, Timpka T, Sedghi S (August 2017). "The Top 100 Articles in the Medical Informatics: a Bibliometric Analysis". Journal of Medical Systems. 41 (10): 150. doi:10.1007/s10916-017-0794-4. PMID 28825158. S2CID 7309349.
  4. ^ Shortliffe EH, Cimino JJ, eds. (2014). Biomedical Informatics: Computer Applications in Health Care and Biomedicine (4th ed.). London: Springer-Verlag. doi:10.1007/978-1-4471-4474-8. ISBN 978-1-4471-4473-1.
  5. ^ Imhoff, M (2002). "Health Informatics". Evaluating Critical Care. pp. 255–256. doi:10.1007/978-3-642-56719-3_18. ISBN 978-3-540-42606-6.
  6. ^ Shortliffe, Edward Hance; Cimino, James J.; Chiang, Michael F., eds. (2021). Biomedical Informatics: Computer applications in health care and biomedicine (5th ed.). Cham, Switzerland: Springer. ISBN 978-3-030-58720-8.
  7. ^ "Core Competency Framework for Clinical Informaticians". Faculty of Clinical Informatics. Retrieved 26 December 2022.
  8. ^ Salehahmadi Z, Hajialiasghari F (January 2013). "Telemedicine in iran: chances and challenges". World Journal of Plastic Surgery. 2 (1): 18–25. PMC 4238336. PMID 25489500.
  9. ^ a b c Pisarchik AN, Maksimenko VA, Hramov AE (October 2019). "From Novel Technology to Novel Applications: Comment on "An Integrated Brain-Machine Interface Platform With Thousands of Channels" by Elon Musk and Neuralink". Journal of Medical Internet Research. 21 (10): e16356. doi:10.2196/16356. PMC 6914250. PMID 31674923. S2CID 207818415.
  10. ^ a b c d Quan XI, Sanderson J (December 2018). "Understanding the Artificial Intelligence Business Ecosystem". IEEE Engineering Management Review. 46 (4): 22–25. doi:10.1109/EMR.2018.2882430. ISSN 0360-8581. S2CID 59525052.
  11. ^ "Microsoft's next big AI project? Helping 'solve' cancer". ZDNET. Retrieved 2024-09-29.
  12. ^ Hoey J, Poupart P, von Bertoldi A, Craig T, Boutilier C, Mihailidis A (2010). "Automated Handwashing Assistance For Persons With Dementia Using Video and a Partially Observable Markov Decision Process". Computer Vision and Image Understanding. 114 (5): 503–19. CiteSeerX 10.1.1.160.8351. doi:10.1016/j.cviu.2009.06.008. S2CID 8255735.
  13. ^ Mihailidis A, Boger JN, Craig T, Hoey J (November 2008). "The COACH prompting system to assist older adults with dementia through handwashing: an efficacy study". BMC Geriatrics. 8: 28. doi:10.1186/1471-2318-8-28. PMC 2588599. PMID 18992135.
  14. ^ Huser V, Shmueli-Blumberg D (August 2018). "Data sharing platforms for de-identified data from human clinical trials". Clinical Trials. 15 (4): 413–423. doi:10.1177/1740774518769655. PMID 29676586. S2CID 4993178.
  15. ^ "Share, Integrate & Analyze Cancer Research Data". Project Data Sphere.
  16. ^ "ImmPort Private Data". National Institute of Allergy and Infectious Diseases (NIAID), National Institutes of Health (NIH). United States Health and Human Services (HHS).
  17. ^ "ClinicalStudyDataRequest.com". ideaPoint, Inc.
  18. ^ Huser V, Sastry C, Breymaier M, Idriss A, Cimino JJ (October 2015). "Standardizing data exchange for clinical research protocols and case report forms: An assessment of the suitability of the Clinical Data Interchange Standards Consortium (CDISC) Operational Data Model (ODM)". Journal of Biomedical Informatics. 57: 88–99. doi:10.1016/j.jbi.2015.06.023. PMC 4714951. PMID 26188274.
  19. ^ a b MacKenzie SL, Wyatt MC, Schuff R, Tenenbaum JD, Anderson N (June 2012). "Practices and perspectives on building integrated data repositories: results from a 2010 CTSA survey". Journal of the American Medical Informatics Association. 19 (e1): e119–24. doi:10.1136/amiajnl-2011-000508. PMC 3392848. PMID 22437072.
  20. ^ a b Wade TD, Zelarney PT, Hum RC, McGee S, Batson DH (December 2014). "Using patient lists to add value to integrated data repositories". Journal of Biomedical Informatics. 52: 72–7. doi:10.1016/j.jbi.2014.02.010. PMC 4134416. PMID 24534444.
  21. ^ a b c d Nadkarni P (2016). "Clinical Data Repositories: Warehouses, Registries, and the Use of Standards". Clinical Research Computing: A Practitioner's Handbook. Academic Press. pp. 173–85. doi:10.1016/B978-0-12-803130-8.00009-9. ISBN 978-0-12-803145-2.
  22. ^ a b Huser V, Cimino JJ (2014). "Don't take your EHR to heaven, donate it to science: legal and research policies for EHR post mortem". Journal of the American Medical Informatics Association. 21 (1): 8–12. doi:10.1136/amiajnl-2013-002061. PMC 3912713. PMID 23966483.
  23. ^ Huser V, DeFalco FJ, Schuemie M, Ryan PB, Shang N, Velez M, Park RW, Boyce RD, Duke J, Khare R, Utidjian L, Bailey C (2016). "Multisite Evaluation of a Data Quality Tool for Patient-Level Clinical Data Sets". eGEMs. 4 (1): 1239. doi:10.13063/2327-9214.1239. PMC 5226382. PMID 28154833.
  24. ^ a b c d e Tenenbaum JD (February 2016). "Translational Bioinformatics: Past, Present, and Future". Genomics, Proteomics & Bioinformatics. 14 (1): 31–41. doi:10.1016/j.gpb.2016.01.003. PMC 4792852. PMID 26876718.
  25. ^ AMIA website
  26. ^ Lyons R (2010). Understanding Digital Signal Processing. Prentice Hall. ISBN 978-0-13-702741-5.
  27. ^ Corley AM (September 2009). "The Reality of Robot Surrogates". spectrum.ieee.com. Archived from the original on September 28, 2009. Retrieved 19 March 2013.
  28. ^ "Pulsed (UV) Light". Top Wiki. Archived from the original on 2018-09-01. Retrieved 2020-12-06.
  29. ^ "On the topic of robotics". Discovery News. Discovery Communications, LLC. Archived from the original on 20 October 2013.
  30. ^ Bayot A (November 23, 2014). "U.S. Military Robots To Join Fight Against Ebola". Inquisitr.
  31. ^ "NYU Graduate Training Program in Biomedical Informatics (BMI): A Brief History of Biomedical Informatics as a Discipline". nyuinformatics.org. NYU Langone Medical Center. Archived from the original on 2010-12-12. Retrieved 11 November 2010.
  32. ^ Priest L (2008-02-18). "Your medical chart, just a mouse click away". The Globe and Mail. Toronto.
  33. ^ "Head of eHealth Ontario is fired amid contracts scandal, gets big package". CBC News. 2009-06-07. Retrieved 2009-08-26.
  34. ^ "The History of Health Informatics". Health Informatics, Nursing Informatics and Health Information Management Degrees. University of Illinois at Chicago. 2014-09-09. Archived from the original on 2012-03-12. Retrieved 2010-11-08.
  35. ^ Sittig DF, Ash JS, Ledley RS (2006). "The story behind the development of the first whole-body computerized tomography scanner as told by Robert S. Ledley". Journal of the American Medical Informatics Association. 13 (5): 465–69. doi:10.1197/jamia.M2127. PMC 1561796. PMID 16799115.
  36. ^ a b November JA (2012). Biomedical Computing: Digitizing Life in the United States. Baltimore: Johns Hopkins University Press. ISBN 978-1-4214-0468-4.
  37. ^ Pyle KI, Lobel RW, Beck JR (1988). "Citation analysis of the field of medical decision making: update, 1959–1985". Medical Decision Making. 8 (3): 155–64. doi:10.1177/0272989X8800800302. PMID 3294550. S2CID 34108803.
  38. ^ Murray MP, Drought AB, Kory RC (March 1964). "Walking patterns of normal men". The Journal of Bone and Joint Surgery. American Volume. 46 (2): 335–60. doi:10.2106/00004623-196446020-00009. PMID 14129683.
  39. ^ "MGH – Laboratory of Computer Science". Archived from the original on 2014-08-02. Retrieved 2009-04-16.
  40. ^ Reilly ED (2003). Milestones in Computer Science and Information Technology. Greenwood Press. p. 161. ISBN 978-1-57356-521-9.
  41. ^ Collen MF (1995). A History of Medical Informatics in the United States, 1950 to 1990. Bethesda, MD: American Medical Informatics Association. ISBN 978-0-9647743-0-8.
  42. ^ Harvard Medical Faculty Physicians. "Historical Videos of the founding of the Division of Clinical Informatics at Beth Israel Deaconess Medical Center". Israel Deaconess Medical Center, Inc.
  43. ^ Harvard Medical Faculty Physicians. "Division of Clinical Informatics at Beth Israel Deaconess Medical Center".
  44. ^ Tanner A (7 January 2017). "Patient power through records". Boston Globe. Retrieved 2 February 2017.
  45. ^ Horowitz GL, Bleich HL (October 1981). "PaperChase: a computer program to search the medical literature". The New England Journal of Medicine. 305 (16): 924–30. doi:10.1056/NEJM198110153051605. PMC 2580387. PMID 7024808.
  46. ^ Safran C (July–August 2002). "Presentation of Morris F. Collen Award to professors Howard Bleich and Warner Slack". Journal of the American Medical Informatics Association. 9 (4): 406–8. doi:10.1197/jamia.M1080. PMC 403635. PMID 12087123.
  47. ^ Turchin A, Florez Builes LF (May 2021). "Using Natural Language Processing to Measure and Improve Quality of Diabetes Care: A Systematic Review". Journal of Diabetes Science and Technology. 15 (3): 553–560. doi:10.1177/19322968211000831. PMC 8120048. PMID 33736486.
  48. ^ Zahabi M, Kaber DB, Swangnetr M (August 2015). "Usability and Safety in Electronic Medical Records Interface Design: A Review of Recent Literature and Guideline Formulation". Human Factors. 57 (5): 805–34. doi:10.1177/0018720815576827. PMID 25850118. S2CID 24450135.
  49. ^ Patton GA, Gardner RM (1999). "Medical informatics education: the University of Utah experience". Journal of the American Medical Informatics Association. 6 (6): 457–65. doi:10.1136/jamia.1999.0060457. PMC 61389. PMID 10579604.
  50. ^ "Clinical Informatics Subspecialty".
  51. ^ Safran, Charles; Shabot, MM; Munger, BS; Holmes, JH; Steen, EB; Lumpkin, JR; Detmer, DE (2008). "Program requirements for fellowship education in the subspecialty of clinical informatics". J Am Med Inform Assoc. 16 (4): 158–66. doi:10.1197/jamia.M3046. PMC 2649323. PMID 19074295.
  52. ^ "Informatics Nursing Certification Eligibility Criteria". American Nurses Credentialing Center. Retrieved 18 June 2016.
  53. ^ "Certification Guide" (PDF). American Board of Imaging Informatics. Retrieved 18 June 2016.
  54. ^ "Knowledge Domains". American Health Information Management Association. Archived from the original on 16 January 2017. Retrieved 18 June 2016.
  55. ^ "Missed Opportunities? The Labor Market in Health Informatics, 2014". Burning Glass Technologies. December 2014. Retrieved 18 June 2016.
  56. ^ "AHIMA Certification Activities 2015". American Health Information Management Association. Archived from the original on 16 June 2016. Retrieved 18 June 2016.
  57. ^ "Health Informatics for Low- and Middle-Income Countries: Short Course for Health Information System Professions – MEASURE Evaluation". measureevaluation.org. Archived from the original on 2018-10-05. Retrieved 2018-10-04.
  58. ^ "Executive Order 13335" (PDF). Federal Register. 69 (84). 30 April 2004 – via U.S. Government Publishing Office. Incentives for the Use of Health Information Technology and Establishing the Position of the National Health Information Technology Coordinator
  59. ^ "CCHIT Announces First Certified Electronic Health Record Products". Certification Commission for Healthcare Information Technology. 18 July 2006. Retrieved 26 July 2006.
  60. ^ "The Department of Biomedical Informatics (DBMI)". Blavatnik Institute. Harvard Medical School.
  61. ^ "Biomedical Informatics Research". Cincinnati Children's Hospital Medical Center.
  62. ^ "Biomedical Informatics |". UC Cincinnati College of Medicine.
  63. ^ "BMI Graduate Program". UC Cincinnati College of Medicine.
  64. ^ "PhD in Bioinformatics and Systems Biology with emphasis in Biomedical Informatics". UCSD Division of Biomedical Informatics. University of California, San Diego. Retrieved 19 November 2024.
  65. ^ "Clinical Research Graduate Curriculum". UCSD Clinical Research Graduate Degree Program. University of California, San Diego. Retrieved 19 November 2024.
  66. ^ "UCSD Course Catalog". UCSD Educational Technology Services. University of California, San Diego. Retrieved 19 November 2024.
  67. ^ "Fifth Framework Programme (FP5: 1998-2002)". CORDIS. European Commission.
  68. ^ "European Patient Smart Open Services". Archived from the original on 2015-08-16. Retrieved 2019-09-18.
  69. ^ "European eHealth Action Plan". European Commission. Archived from the original on 19 March 2011.
  70. ^ "European eHealth Action Plan i2010". European Commission. Archived from the original on 6 December 2010.
  71. ^ "Electronic Health Records for Europe". European Space Agency. 2005. Retrieved 2009-01-13.
  72. ^ "UKCHIP". Archived from the original on 27 February 2018.
  73. ^ "GP Systems of Choice (GPSoC)". National Health Service. United Kingdom.
  74. ^ "Number of primary care IT suppliers to quadruple". Health Service Journal. 22 October 2019. Retrieved 1 December 2019.
  75. ^ "British Computer Society". Retrieved 14 August 2022.
  76. ^ "Faculty of Clinical Informatics". Archived from the original on 14 August 2022. Retrieved 14 August 2022.
  77. ^ "Federation for Informatics Professionals". Retrieved 14 August 2022.
  78. ^ "Core Competency Framework Reports". The Faculty of Clinical Informatics. Archived from the original on 20 September 2022. Retrieved 19 September 2022.
  79. ^ "English | About the NFU". Archived from the original on 2023-03-08. Retrieved 2016-12-19.
  80. ^ "Patiëntenzorg | Citrienfonds". Archived from the original on 2020-10-05. Retrieved 2016-12-19.
  81. ^ "Netherlands". 2 October 2019.
  82. ^ "English". Archived from the original on 2017-09-24. Retrieved 2016-12-19.
  83. ^ "Asia Pacific Association of Medical Informatics".
  84. ^ "Australasian College of Health Informatics". Retrieved 3 May 2010.Australasian College of Health Informatics
  85. ^ "International Medical Informatics Association – Academic Institutional Members". Australian College of Health Informatics. 12 August 2009. Archived from the original on 6 July 2010. Retrieved 22 February 2010.
  86. ^ "ACHI Memberships". Australasian College of Health Informatics (ACHI).
  87. ^ "eJHI Journal of Health Informatics". Archived from the original on 2011-07-23. (open access journal)
  88. ^ "AHIEC Auspicing Organisations". Australian Health Informatics Education Council (AHIEC).
  89. ^ "Health Informatics Society of Australia Ltd". Retrieved 3 April 2010.
  90. ^ a b Zhang Y, Xu Y, Shang L, Rao K (August 2007). "An investigation into health informatics and related standards in China". International Journal of Medical Informatics. 76 (8): 614–20. doi:10.1016/j.ijmedinf.2006.05.003. PMID 16793329.
  91. ^ Guo J, Takada A, Niu T, He M, Tanaka K, Sato J, Suzuki M, Takahashi K, Daimon H, Suzuki T, Nakashima Y, Araki K, Yoshihara H (October 2005). "Enhancement of CLAIM (clinical accounting information) for a localized Chinese version". Journal of Medical Systems. 29 (5): 463–71. doi:10.1007/s10916-005-6103-7. PMID 16180482. S2CID 17540005.
  92. ^ Wang XJ, Hu J, Wang K, Yu H, Luo M, Lei WY (November 2004). "Setting-up and preliminary performance of the interactive teleradiological conference system based on virtual private network". Chinese Medical Journal. 117 (11): 1735–38. PMID 15569497.
  93. ^ Rao KQ, Wang CY, Hu JP (2005). "Introduction of the National Public Health Emergency Response Information Systems Project". Chinese Journal of Integrative Medicine. 1: 2–5.
  94. ^ Wu MX, Yu P, Soar J (December 2003). "The Current Status of Health Informatics Higher Education in China" (PDF). Health Informatics Journal. 9 (4): 211–23. doi:10.1177/1460458203094008. S2CID 1699875.
  95. ^ Kim J, Piao M, Jingwu W (March 2009). "The Current Status of Hospital Information Systems in Yanbian, China" (PDF). Journal of Korean Society of Medical Informatics. 15 (1): 133–40. doi:10.4258/jksmi.2009.15.1.133. hdl:10371/81954. Archived from the original (PDF) on 10 July 2020.
  96. ^ "Development Layout of National Health Information". Retrieved 2017-11-03.
  97. ^ Kalra D, Beale T, Heard S (2005). "The openEHR Foundation". Studies in Health Technology and Informatics. 115: 153–73. PMID 16160223.
  98. ^ Xu W, Guan Z, Cao H, Zhang H, Lu M, Li T (August 2011). "Analysis and evaluation of the Electronic Health Record standard in China: a comparison with the American national standard ASTM E1384". International Journal of Medical Informatics. 80 (8): 555–61. doi:10.1016/j.ijmedinf.2011.05.003. PMID 21680236.
  99. ^ Lévy PP, Duché L, Darago L, Dorléans Y, Toubiana L, Vibert JF, Flahault A (2005). "ICPCview: visualizing the International Classification of Primary Care". Studies in Health Technology and Informatics. 116: 623–28. PMID 16160327.
  100. ^ "Health informatics section in Hong Kong Hospital Authority".
  101. ^ "eHealth Consortium". Internet Professional Association Limited. Archived from the original on 2006-06-28.
  102. ^ "eHCF School of Medical Informatics".
  103. ^ "eHealth-Care Foundation".
  104. ^ Kerr K, Cullen R, Duke J, Holt A (2006). "Health Informatics Capability Development in New Zealand – A Report to the Tertiary Education Commission" (PDF). Archived from the original (PDF) on 2008-09-20. Retrieved 2009-01-08.
  105. ^ "Medical Pharmaceutical Information Association (MedPharmInfo)". Imia.org. 2008-05-18. Retrieved 2010-07-29.[permanent dead link]
  106. ^ "Saudi Association for Health Informatics (SAHI)". sahi.org.sa. Archived from the original on 2010-08-24.
  107. ^ Ericksen AB (July 2009). "Informatics: the future of nursing". Rn. 72 (7): 34–7. PMID 19645226.
  108. ^ Menachemi N, Collum TH (2011). "Benefits and drawbacks of electronic health record systems". Risk Management and Healthcare Policy. 4: 47–55. doi:10.2147/RMHP.S12985. PMC 3270933. PMID 22312227.
  109. ^ a b c Your Rights Under HIPAA. (n.d.). [Text]. Retrieved September 5, 2016, from "Your Rights Under HIPAA". U.S. Department of Health & Human Services. 7 May 2008.
  110. ^ Nelson R, Staggers N (2014). Health Informatics: An Interprofessional Approach. St. Louis: Mosby. ISBN 978-0-323-10095-3.
  111. ^ "NLM Catalog". National Center for Biotechnology Information. U.S. National Library of Medicine. 2016.
  112. ^ "Journals Ranked by Impact: Medical Informatics". 2018 Journal Citation Reports. Web of Science (Science ed.). Clarivate Analytics. 2019.
  113. ^ "Clinical informatics". American Board of Pathology. Archived from the original on 2022-02-12. Retrieved 2022-02-12.
  114. ^ "Clinical Informatics". American Board of Preventive Medicine. Retrieved 2022-02-12.
  115. ^ "Clinical Informatics 2014 Diplomats". American Board of Preventive Medicine. December 2013. Archived from the original on 8 January 2014. Retrieved 7 January 2014.
  116. ^ "Clinical Informatics Board Certification" (PDF). American Board of Preventive Medicine. 1 January 2013. Archived from the original (PDF) on 29 December 2013. Retrieved 7 January 2014.

Further reading

[edit]
[edit]