Telehealth's New Horizon: Providing Smart Hospital-Level Care in the Home.

During the COVID-19 pandemic, medical providers have expanded telehealth into daily practice, with many medical and behavioral health care visits provided remotely over video or through phone. The telehealth market was already facilitating home health care with increasing levels of sophistication before COVID-19. Among the emerging telehealth practices, telephysical therapy; teleneurology; telemental health; chronic care management of congestive heart failure, chronic obstructive pulmonary disease, diabetes; home hospice; home mechanical ventilation; and home dialysis are some of the most prominent. Home telehealth helps streamline hospital/clinic operations and ensure the safety of health care workers and patients. The authors recommend that we expand home telehealth to a comprehensive delivery of medical care across a distributed network of hospitals and homes, linking patients to health care workers through the Internet of Medical Things using in-home equipment, including smart medical monitoring devices to create a "medical smart home." This expanded telehealth capability will help doctors care for patients flexibly, remotely, and safely as a part of standard operations and during emergencies such as a pandemic. This model of "telehomecare" is already being implemented, as shown herein with examples. The authors envision a future in which providers and hospitals transition medical care delivery to the home just as, during the COVID-19 pandemic, students adapted to distance learning and adults transitioned to remote work from home. Many of our homes in the future may have a "smart medical suite" as well as a "smart home office."

A Life Well Lived: In Memory of Máximo E. Valentinuzzi.

Throughout his career, Dr. Máximo (Max) E. Valentinuzzi worked long and hard for the development of the BME profession locally, regionally, and internationally. His accomplishments were numerous and valuable, including his editorship of the IEEE Pulse special column known as "Retrospectroscope" for more than ten years. A highlight and strength of the magazine over the past decade, this special column was built largely on the efforts and contributions from Dr. Valentinuzzi (Figure 1).

Cybercare 2.0: meeting the challenge of the global burden of disease in 2030.

In this paper, we propose to advance and transform today's healthcare system using a model of networked health care called Cybercare. Cybercare means "health care in cyberspace" - for example, doctors consulting with patients via videoconferencing across a distributed network; or patients receiving care locally - in neighborhoods, "minute clinics," and homes - using information technologies such as telemedicine, smartphones, and wearable sensors to link to tertiary medical specialists. This model contrasts with traditional health care, in which patients travel (often a great distance) to receive care from providers in a central hospital. The Cybercare model shifts health care provision from hospital to home; from specialist to generalist; and from treatment to prevention. Cybercare employs advanced technology to deliver services efficiently across the distributed network - for example, using telemedicine, wearable sensors and cell phones to link patients to specialists and upload their medical data in near-real time; using information technology (IT) to rapidly detect, track, and contain the spread of a global pandemic; or using cell phones to manage medical care in a disaster situation. Cybercare uses seven "pillars" of technology to provide medical care: genomics; telemedicine; robotics; simulation, including virtual and augmented reality; artificial intelligence (AI), including intelligent agents; the electronic medical record (EMR); and smartphones. All these technologies are evolving and blending. The technologies are integrated functionally because they underlie the Cybercare network, and/or form part of the care for patients using that distributed network. Moving health care provision to a networked, distributed model will save money, improve outcomes, facilitate access, improve security, increase patient and provider satisfaction, and may mitigate the international global burden of disease. In this paper we discuss how Cybercare is being implemented now, and envision its growth by 2030.

A proposal to enhance Engineering education in biology and Medicine by following the legacy of René Favaloro.

The synergy amongst Engineering, Medicine and Biology evolves as fast as these disciplines. We propose to articulate these specialties based on the premise that new professionals must face different situations or crisis due to the so-called islands of excellence. René Favaloro focused his work and struggles against poverty, since malnutrition and environmental degradation may increase the propensity to cardiovascular diseases. Doctor Favaloro has dedicated, throughout his career, a considerable amount of time to prepare and qualify a research group, aware of the importance that an adequate working environment has over the final results. He created a team of young students, engineers, medical doctors, physicists, mathematicians and other specialists. He centered his attention on human resources, in order to disseminate his latest advances in Biology, Medicine and Engineering. We are revising the programs of biomedical engineering education and the application of new pedagogic paradigms, where critical thinking is the key: a holistic challenge that consists of a new way of learning, innovating, communicating and shearing, with a creative attitude that represents quality of perception.

Envisioning patient safety in Telehealth: a research perspective.

This article explores the need for research into patient safety in large-scale Telehealth systems faced with the perspective of its development extended to healthcare systems. Telehealth systems give rise to significant advantages in improving the quality of healthcare services as well as bringing about the possibility of new types of risk. A theoretical framework is proposed for patient safety for its approach as an emerging property in complex socio-technical systems (CSTS) and their modelling in layers. As regards this framework, the differential characteristic Telehealth elements of the system have been identified, with a greater emphasis on the level of Telehealth system and its typical subsystems. The bases of the analysis are based on references in the literature and the experience accumulated by the researchers in the area. In particular, a case describing an example of Telehealth to control patients undergoing treatment with oral anticoagulants is used. As a result, a series of areas of research into and topics regarding Telehealth patient safety are proposed to cover the detectable gaps. Both the theoretical and practical implications of the study are discussed and future perspectives are reflected on.

Improving outcomes with interoperable EHRs and secure global health information infrastructure.

One of the central pieces for healthcare and public health is information. Through the shared use of the Information Super Highway and the WWW, for example, elder patients can, and indeed are "visited, diagnosed, treated and managed" from their homes, with the help of telemedicine systems. These technologies also provide society with additional benefits within a global health perspective, with applications ranging from disease prevention and genetics to surveillance and epidemiologic studies. For example, discoveries relating to the prevention or curing of a disease in one part of the world should be "known" everywhere else instantaneously. During an emergency, individuals travelling the world should be able to access their healthcare records for proper care, anywhere. Individuals emigrating from a country to any other should be able to use their information "seamlessly" in terms of the "old" and "new" information systems, no matter where they are. The information contained in multiple systems, i.e., civilian, military forces, etc., should appear transparently among all. However, at this time, significant questions regarding privacy of health information, quality of the services delivered and in general, the information assurance, i.e., authenticity, confidentiality, integrity, availability, and non-repudiation persists. A common aspect to information protection and sharing is interoperability. The authors believe that this term is poorly understood and consequently its incorrect use generates immensely negative consequences. The question raised by the authors then is, what is "true interoperability"?

The use of technology to transform the home into a safe-haven.

On June 14, 2006 three reports were published by the Institute of Medicine (IOM) in regards to "THE FUTURE OF EMERGENCY CARE IN THE UNITED STATES HEALTH SYSTEM". The three combined reports: Hospital-Based Emergency Care at the Breaking Point, Emergency Medical Services at the Crossroads and Emergency Care for Children Growing Pains, are a clear reflection of the state we currently face, even without a major disaster. Some key findings drawn from all three reports showed that the emergency care system is ill-prepared to handle a major one. For example, many of the 41 million citizens who do not have medical insurance end up using the Emergency Departments (ED) as their source of "regular" care and many of these EDs are at or over capacity, there is little surge capacity for a major event, whether it takes the form of a natural disaster, disease outbreak, or terrorist attack. If we had during the major disaster event, a "contagion" element, i.e. pandemic flu, then the problem would be even more complicated, since the "regular" hospital patient population would need to be isolated from these patients. If we add to this equation the length of time involved in the "current" process of vaccine creation and production (i.e. the volume of vaccines that would be required to be provided to the citizens of the world), the scenario does not look to promising. A new model is needed then to address these requirements. In the developed world we have a number of devices (e.g., radio, TV, Computers, telephones, mobile devices, etc.) and infrastructure (e.g., cable, wireless networks, etc.) that are already supplying the homes and the individuals with a large number of independent applications and different types of information. These stovepipes or independently developed family that include: tele-banking, Telehealth, tele-education, e-commerce, entertainment on demand, etc. when "connected" as an integrated set, may provide an ideal environment, where families may stay at home for a long period of time (quarantine) and would have all the mechanisms in place for getting food and water from supermarkets, drugs from the pharmacy, the children would be able to go to school from home (in turn their school grounds may become temporary hospitals), adults could telecommute to work and minor conditions could be consulted and treated through these systems (with the help of a Telehealth platform that would include electronic health records), etc.