Join us at the 3rd annual Emerging Tech in Health symposium in Christchurch on 21+22 May
ETIH19 is part of NZ Tech Week'19.
Attend one day or both, depending on your areas of interest:
Health Informatics New Zealand (HiNZ) is a not-for-profit organisation with a focus on events, education and networking. HiNZ supports the field of health informatics and runs a range of events. Its annual conference is the largest digital health event in New Zealand and it has an extensive archive of expert presentations on digital health. HiNZ delegates and members come from a diverse range of areas within healthcare, technology, and government. HiNZ builds and strengthens connections between these groups and provides an impartial meeting place for sharing ideas and building knowledge about the use of IT in the health sector. HiNZ offer students a free membership and discounted rates for our events/conferences.
For details for students please refer to https://www.hinz.org.nz/page/Studentmember
The common theme to highlight for the International Women’s Day is #BalanceForBetter
Gender Equality is for all genders, not just women. In 2019, however women still struggle to rise up the ranks of both health and science. Gender discrimination, implicit bias, sexual harassment, and assault have been found to be systemic barriers to women’s advancement in global health careers.
Female health workers comprise 70% of the health workforce worldwide yet women occupy only 25% of leadership positions in health and just 12% of the membership of national science academies worldwide.
However, we are keep seeing positive signs that things are changing, better work arrangement, more comprehensive policies on gender discrimination and harassment, more and more mentorship programme and leadership training for female… And all these help us to overcome the challenges and empowering women in act independently and powerfully in global health.
On 27th May, we are hosting a Women in Health IT Conference in Auckland, New Zealand. Together, we can do better.
The Women in Health IT conference brings together established and emerging leaders from across sectors and cultures to work towards gender equity in health leadership and to improve health for all.
Join us in addressing the gender gap in health information and technology, and the need for more community, resources and recognition of women who have made a difference sector-wide. Engage with your peers and take the next step to further your career while connecting with and empowering women in our field.
This conference is open to all genders. #BalanceForBetter
Recently, Deloitte released a report entitled “2019 Global Health Care Outlook: Shaping the Future”, which details the above situation and introduces existing feasible solutions. The Arterial Network compiled and compiled some of the contents of the report for you. The following are the core points:
Global health care spending is expected to grow at a rate of 5.4% per year in 2018-2022, compared to 2.9% per year in 2013-2017.
This increase reflects the strength of the dollar against the euro and other currencies, the expansion of coverage of health insurance in developing markets, the increased demand for care for the elderly, advances in medical technology, and rising medical labor costs.
Per capita health care spending is expected to continue to vary widely, from $11,674 in the United States to $54 in Pakistan in 2022. Efforts to close this gap will be limited by the acceleration of population growth in developing countries.
Higher per capita spending does not always mean higher quality health care services. Compared with 10 developed countries, the United States ranks unsatisfactory in terms of overall health care performance, which is highlighted by a 50% higher per capita expenditure than the countries ranked after it, but ranked in terms of efficiency, fairness and healthy living.
Life expectancy seems to continue to climb. It is estimated that by 2022, the average life expectancy of the population over 65 years old will increase from 73.5 years in 2018 to 74.4 years, more than 668 million, accounting for 11.6% of the global population. Increasing life expectancy and life expectancy is a major achievement in health care, as the increase in per capita output is related to an increase in real per capita GDP.
This effect is expected to be most pronounced in Japan, which is likely to reach nearly 29%. In Western Europe, this ratio is estimated to be close to 22%. Even some developing countries such as Argentina, Thailand and China have begun to see similar situations.
Efforts to combat infectious diseases are making significant progress by improving sanitation, improving living conditions and wider access to health care services. Thanks to advances in medical technology, the number of AIDS-related deaths has fallen from 2.3 million in 2005 to 940,000 in 2017. Tuberculosis infections are down by about 2% per year. The number of malaria deaths worldwide has fallen from nearly 1 million in 2000 to 445,000 in 2016. The widespread use of new vaccines and treated nets reduces the infection rate and mortality of all mosquito-borne diseases.
Noncommunicable diseases Cancer, heart disease and diabetes accounted for 71% of the 56.9 million deaths reported globally in 2016. In most developed markets, this proportion has exceeded 80%. Urbanization, sedentary lifestyles, changing diets and rising levels of obesity are driving the growth of non-communicable diseases markets in both developed and developing countries.
Health care stakeholders—health care providers, governments, payers, consumers, and other companies/organizations—are working to meet clinical, operational, and financial challenges. Looking to the future, with the help of digital technology, new business and health care delivery models may help solve today's problems and build a sustainable foundation for affordable, accessible, high-quality health care.
This idea is more likely to become a reality. If all stakeholders are actively involved in shaping the future, it is necessary to shift the focus of philosophy from the disease care system of patients after illness treatment to health care that supports health, prevention and early intervention. system.
However, today's healthcare systems and participants are unlikely to achieve this transformation on their own. They may need to work with other traditional sectors such as employment, housing, education and transportation to address healthy social determinants and work with new sectors such as retail, banking and technology giants to improve data and platform interoperability.
The potential of “digitalization” in the “business core” operations
Cutting-edge technologies that patients, members, and customers can see can help healthcare organizations stand out. But the core technology, the technology that most people have never seen before, can make an organization work. Back-ofce systems and their quality of connectivity to front-end enterprise functions are key infrastructures that enable pricing, product availability, logistics, quality, finance, and other "business core" information to be used when needed.
While health care organizations are embarking on digital empowerment from multiple perspectives, one issue is always important: using emerging technologies to redefine core systems and back-end processes to define how day-to-day work is done .
Some supplier organizations have begun to take steps to improve their two main core functions: machine learning and robotic process automation (RPA), cloud-based software-as-a-service (SaaS) and forecasting tools: revenue cycle and supply chain.
Significant advances in wireless technology, miniaturization and computing power have led to an exponential increase in the speed and scale of digital healthcare innovation, where innovation is emerging and affecting clinical and commercial operations. These advances have also prompted consumers to increasingly expect “digitalization”, which seems to be a new demand for all medical institutions.
Digital innovations such as blockchain, cloud computing, virtual health, artificial intelligence and robotics, digital reality, medical Internet of Things (IoMT) are helping to reshape the future of healthcare, making healthcare more efficient and accessible. Increasing data access and data sharing through digital solutions is improving personalized self-service and patient experiences.
More benefits from digitalization may be at hand. For example, blockchain has the potential to enhance collaboration, trust, interoperability, and traceability in a range of functions including clinical trials, supply chain management, financial transactions, certification, and claims processing. Sex and auditability.
In the life sciences and health care sectors, the transition from blockchain to blockchain (the network of networks) is particularly striking. In this area, different sectors work together in a broadly interdependent ecosystem.
The industry application of blockchain is still in its infancy, but a survey by Deloitte shows that the number of life sciences and medical institutions (35%) planned to deploy blockchain in 2017 exceeds similar expectations in other industries.
Health systems around the world are investing in digital technology with varying degrees of enthusiasm
Australia is launching the My Health Record (PHR) service, which links patients' personal health record data to different parts of the health value chain and patients can opt out.
The UK recently announced an investment of 37.5 million euros to establish a digital innovation center to address the UK's biggest health challenges. In other digital developments, more and more people in the country use the innovative company Babylon Health as a way to get primary care. New members of the healthcare industry are entering the EHR market, which may reduce the overall cost of implementation. In addition, they have a number of activities in automated AI-assisted diagnostics, remote health and comprehensive health records.
In 2017, the Chinese government issued the “13th Five-Year” National Science and Technology Innovation Program, aiming to develop precision medical technology and integrate it into a multi-level knowledge base to create a national biomedical big data sharing platform. Over time, with the support of evidence-based technology, patients who are about to receive treatment or are receiving treatment will benefit from better quality of service and personalized care.
A new Japanese law is expected to significantly increase the sharing of electronic medical record (EMR) data. Almost all hospitals in Japan have electronic medical records. The problem is that each hospital uses a slightly different system. Therefore, data is not designed to be aggregated at the national level and is not the best way to improve national health systems. In addition, the hospital's electronic medical records should be linked to the primary care data set to provide a true understanding of the patient's path.
In the Netherlands , patient-centred healthcare is supported by electronic health solutions and is a top priority for hospitals and healthcare organizations. However, the goal of the health system is to go beyond the pilot and move toward mainstream applications.
Ba Xi some of the company's human resources department is to increase employee participation in health and chronic care programs through the game of.
India 's health system is launching many conceivable and cutting-edge small-scale pilot projects around mobile health, telemedicine and IoMT, although they are rarely implemented on a large scale. Many public and private hospitals are turning to online patient registration and service delivery systems, and digital marketing is becoming more commonplace through appointments, online payments, downloading test reports, and sharing health tips.
A list of digital technologies that can help healthcare providers, payers, and governments achieve the three goals of improving healthcare, improving health, and reducing spending are expanding and growing. Let's take a closer look at three of these innovations: artificial intelligence and robotics, digital reality, and the Medical Internet of Things (IoMT).
Focus on digital medical innovation
Artificial intelligence and robots
Artificial intelligence is expected to change the healthcare industry by performing clinical and commercial tasks currently performed by humans faster and more accurately, and using fewer resources.
Artificial intelligence can provide decision support and physician assistance for tasks such as diagnosing patients and early detection of disease outbreaks; speeding up the development of new drugs and equipment; streamlining the Chief Executive's middle and post functions, such as doctor referrals, patient path coding, and claims approval.
An example of artificial intelligence-assisted workflow management is DeloitteASSIST, a patient communication solution that combines speech recognition, natural language processing, and artificial intelligence to enable patients to request help without pressing a button.
By simply saying the request, the nurse can understand their needs, prioritize the request through artificial intelligence, and route it intelligently to the appropriate resources (caregiver, patient support assistant, volunteer) to meet the patient's needs. demand.
Importantly, healthcare stakeholders need to recognize that artificial intelligence technology is designed to support and increase staff so that highly trained resources can focus on more valuable, patient-oriented activities rather than replacing them. . For example, robotics can improve the formulation of drugs, disinfect medical devices, and reconfigure human resources into more valuable areas.
Driverless cars can take patients to see a doctor and improve the continuity of care. Drones can pick up drugs that the old man falls on the ground. The use of robots in pharmacies and surgery is currently in use, although the full potential of the technology has not yet been realized.
In some applications, such as surgery, the cost of these technologies remains a challenge, and it is unclear whether the use of robotics can improve efficiency and effectiveness to justify increased costs.
Artificial intelligence and robotics applications are still in the early stages of adoption among healthcare stakeholders and patients. Increased acceptance may depend on the innovator's ability to reduce costs and improve the accuracy of natural language processing, big data and cognitive technologies, as well as the acceptance and trust of healthcare professionals and patients with new tools.
AliveCor is the maker of the iPhone's KardiaMobile ECG monitor and Apple Watch's KardiaBand ECG recorder, which is collecting data from its devices, which may one day be entered into a machine learning system to help doctors find the disease.
In a potential application, “bloodless testing” will observe subtle changes in the ECG, which is a characteristic of elevated levels of potassium, and artificial intelligence has unique skills in identifying this feature. Measuring the indicator in real time with the convenience of a cell phone or smart watch may change the way clinicians treat their patients after a heart attack.
Digital Reality (DR) is a general term for augmented reality (AR), virtual reality (VR), mixed reality (MR), 360-degree and immersive technologies. With the advent of many new digital features, these technologies have entered the consumer world for the first time in the form of games and entertainment.
Now, the use of these technologies is reaching a tipping point, and companies and organizations are beginning to use more than entertainment. Barriers to technology, cost and content are beginning to diminish, and early adopters are already working hard to create solutions to help change health care.
Deloitte and McLaren are working together to create a data-driven solution that combines specialized hardware and software with sophisticated algorithms to improve the performance of each function and organization. Healthcare applications can include creating digital copies of hospital processes, then applying advanced analytics and running millions of potential scenarios to identify root causes and test different interventions before applying.
In the life sciences and healthcare sectors, the virtual patient simulation market is expected to grow at a rate of nearly 20% per year and will become a $1.5 billion industry by 2025.
Among suppliers, the use of AR and VR is currently concentrated in several discrete areas. For patients, these techniques can speed up their understanding of the condition or treatment plan. When technology is used for imagination and relaxation exercises, they can even be used as a treatment. Applications in opioid addiction treatment, phantom limb treatment, phobia treatment, cancer treatment planning, perioperative planning, post-traumatic stress disorder and general pain management have been established.
DR tools can help maintain mental acuity by participating in certain situations, and some VR-based therapies are beginning to appear to help Alzheimer's patients improve their memory.
In a clinical setting, AR and VR can help doctors and care teams perform care work. For example, the surgeon can use a heads-up display to provide a data coverage of the patient's body during the procedure or to visualize the entire procedure in a preoperative plan.
In combination with medical imaging, augmented reality technology is beginning to provide clinicians with the ability to project medical images (such as CT scans) directly onto the patient and to be consistent with the patient's body, even as the patient moves, augmented reality is also The clinician provides the ability to project a clearer line of sight onto the internal anatomy.
In the context of education, courses in undergraduate, postgraduate, continuing medical education programs and institutions are increasingly being combined with AR and VR support. Take the physician VR training as an example.
Physician VR training
Virtual reality technology The immersive experience and real-life scenarios of surgeons and emergency doctors are changing the process of medical training. The latest developments in VR training include:
Surgical Theater is a VR specialist that provides pre-operative rehearsal platforms for complex surgeries.
The Johnson & Johnson Institute has recently launched a VR training program to help orthopedic surgeons and nurses prepare for total knee arthroplasty and hip fracture treatment procedures, and plans to expand to other operations.
Oculus VR is conducting a trial to test VR simulations of emergency department (ED) staff in high-risk child trauma situations.
London-based Fundamental VR has developed a “Fundamental Surgery” virtual reality application that simulates the surgical environment and the physical feel of the body.
Embodied Labs produced a VR program called We Are Alfred, in which Alfred is a 74-year-old macular degeneration. The device places the nurse or doctor in an individual location of the extreme patient so that they can understand the patient's condition.
Medical internet of things
The Medical Internet of Things (IoMT) is an infrastructure that connects medical devices, software applications, health systems, and services. IoMT combines people (patients, caregivers and clinicians), data (patient or performance data), processes (care delivery and patient support) and startup procedures (sensors, connected medical devices and mobile applications) to be more effective Improve patient outcomes.
The rise in the number of medical devices capable of generating, collecting, analyzing, or transmitting health data or images and connecting to provider networks, transferring data to cloud repositories, or internal servers has driven the rise of IoMT. Importantly, IoMT generates intelligent and measurable information to help more effectively improve the speed and accuracy of diagnosis and treatment
As new technologies evolve, new business models will emerge, and these new business models are expected to have a profound impact on the development of healthcare as they blur the boundaries and promote cross-sectoral and cross-industry integration.
The resulting “super cluster” of public and private sector providers, payers and market disruptors can use the smart health community approach to drive innovation, increase availability and affordability, and improve through more efficient delivery models. Quality and cost reduction
Article retrieved from Wang Shiwei arterial new medicine
Here is a “hello” from the other side of the world. While writing this month’s newsletter, I am currently waiting for my flight to Tokyo, Japan. In the past few Health-Tech conferences held this year, we have studied Health Informatics cases of how the Japanese government is withstanding Japan’s aging population by spreading the use of technical products. Japan is also taking a leading role in the field of medical research and technology innovation. On 22nd November, I will attend the "HOSPEX Japan 2018” exhibitions, which bring together hundreds of medical and technology companies in the Tokyo Big Sight.
I also have the honor to attend one of the biggest health-tech conferences of the year in Japan. The “Health 2.0 Asia” annual conference has picked Tokyo this year. Health 2.0 has started in California in 2007 and keeps its outstanding position to introduce cutting-edge technologies in healthcare technology. As the management team announced the merge with HIMSS last year, this year's conference accelerates its progress more than ever. It will be my pleasure to share useful market resources with you, so please keep an eye on our newsletter and Facebook.
It has been a year since the establishment of the Healthcare Technology Association. The size of our community has expanded tremendously; we are able to reach more talented and active young professionals in the Auckland region, as well as the rest of New Zealand. We successfully held three professional networking events from June to December this year, including one event hosted by the University of Auckland. We are expecting more regular events to be held next year, and we cannot wait to see you again. I and the rest of the HTA committee would like to wish you a Merry Christmas and a happy new year. We believe every step we have taken together and every single connection we built will accelerate the process of health tech integration.
Christiane and the HTA team
Director of the AUT Centre for eHealth and former Clinical Psychologist, Dr Duncan Babbage explains the purpose of his face-name recognition app ‘Intro’. He gives insight on what cognitive prosthetics are and what features the holy grail of one would have—as well as why learning from your mistakes isn’t how you should learn.
Highlighting future aims of the industry from personalized medicine—which is already being implemented locally through kiwi cardiologists who have genome sequencing machines on their desk—to clinician efficiency having the potential to be improved through health technology. Possibilities are endless in this field you should have on your radar. Dr Babbage shares his thoughts.
Q: What did you visualize Intro would do for people going through neurorehabilitation?
Dr Duncan Babbage: The Intro app (http://intro.app) came out of work I was doing with people with significant brain injuries, and partly out of my own experiences. Personally, there would be times I would see someone I should have known relatively well and have no idea who they were, or sometimes I would know exactly who they were but still wouldn’t be able to retrieve their name. And so for me, it’s been a real challenge for years.
Alongside this, I was doing work with people with significant brain injuries, which developed into an interest in the face-name recognition difficulties experienced by some people with brain injuries also. Dr Phil Howard, a clinical psychologist who did his doctoral studies with me, focussed his research on how to support people with brain injuries who had these difficulties to be more effective at these kinds of tasks. He and I developed a prototype app as part of that research. While that app was separate from Intro, and took a somewhat different focus, it was the the start of a journey.
Along the way, I heard from lots of people in the general population who said, “I really need an app like that!” Intro is the result. The purpose of Intro is to give people a tool to help them be more effective at learning names. Intro is starting from some of the same problem space as that earlier research, but explicitly focuses firstly on the general population—with the likelihood that it will be applicable with some people with brain injury as well and that’s actually the ideal cognitive prosthetic.
Babbage breaks down face-name learning in the Intro app through two key principles of Errorless Learning and Spaced Retrieval.
Babbage: Errorless learning research demonstrated that for people who have any difficulty remembering something, the last thing you ever want to do is make a mistake. We say people learn from their mistakes, but actually mistakes very powerfully compete with your ability to correctly recall the right answer.
The right way to learn something new, if you’re going to have any difficulty remembering it, is to always get it right every time. Use as many supports as you need to make sure you keep getting it right and then gradually remove those training wheels, so you continue to get it right without ever making a mistake. That’s ‘errorless learning’—don’t let yourself make any errors.
The tricky thing is it’s hard to give yourself an errorless learning experience. In trying to learn someone’s name, the real world might only give me three or four opportunities to hear it before it’s assumed I should know this person’s name—and maybe I need to hear that name thirteen times. It’s socially difficult to get the extra ten, so if you have a tool like Intro that can help you get that extra practice, that’s great.
The other principle underlying Intro’s name learning tool is spaced retrieval. The way your brain decides what you still need to store is do you use that piece of information or not? The things that are still going to be retrievable later are the things you’ve continued to access over time. Your brain says, ‘this is clearly important—I will make sure to maintain and improve the connection of this information’—and so you can recall it again. Again, activating this function is powerful. You can make efforts to do this yourself, but it’s fairly impractical to do this systematically without a tool that ensures you’re getting this carefully graded experience.
Q: What are cognitive prosthetics and how do you think they will be playing a part in future healthcare?
Babbage: A cognitive prosthetic is any tool that helps your brain processes be more effective than they otherwise would be. They should be something you want to integrate with your day to day life, be as easy to use as possible, and be something that will continue to support your functioning over time, rather than being a training tool that just goes away.
In the context of people who have a neurological impairment of some kind there are a few things that make a cognitive prosthetic better. One of them is that it’s something that is desirable to use—something that looks like something your peers would use. So a smartphone is great because it’s normal… there’s nothing abnormal about it. The third thing that makes a great cognitive prosthetic is if you can pick it up and use it correctly the first time, without any training. That’s the holy grail for a cognitive prosthetic, because it means that even if you forget any training you have received, you’ll still use it correctly. And that, of course, contributes to an errorless learning process.
Usability testing and thinking about how to simplify as much as possible the tools that we’re creating is really important. At the recent /dev/world software development conference in Melbourne (26-28 August), I spoke about practical approaches to cognitive accessibility in software design. One of the starting points of that talk was suggesting to software designers and devlopers that thinking about designing software for people with brain injuries is a really good idea, because we often overcomplicate our solutions. This therefore leads to better tools for everyone. I also talked at that conference about mechanisms for providing users with choice about the level of complexity they want to have in a tool like a mobile app—would they prefer the standard interface, a simpler interface that provides only the most central one or two features of the app, or do they want expert mode, with maximum features and controls? Giving greater flexibility again provides better experiences for everyone.
Q: What do you imagine healthcare to look like in 10 years with reference to technological advancements?
Babbage: I think the future of technology in healthcare is in most cases not nearly as sci-fi as people imagine—but hopefully it's much more important in terms of actually creating some useful change. A big part of that is going to be solving how we close up the gaps in health information storage in ways that give end users both more control over their information and also more access to it—enabling them to get a better insight into what’s going on in their own health.
Personalized medicine is often the term which is used, referring to analysing your genetics and then deciding what treatment you should receive on the basis of your genome. There’s a cardiologist at Auckland Hospital that has a genome sequencing machine on his desk. By sequencing the genome of patients he’s able to ensure that patients who would not benefit from the standard medication can go straight to one that will actually protect them.
Babbage carries on to explain hearing about a subgroup of Pacific Islanders that aren’t responsive to the first line of heart medication so through using this system they’re able to be put on the treatment that will actually work. Babbage says this is a great practical example of personalized medicine actually at work in New Zealand, stressing the importance of making sure information doesn’t get into the wrong hands and is there to better the people of the country.
Babbage: It’s about increasing population health, vitality and our autonomy as New Zealanders—rather than feeding into the disparities between rich, super healthy people and poor downtrodden people.
Q: What is an area in health that you feel has a lot of potential for positive change through introducing or increasing technological advancements?
Babbage: Clinician efficiency. I just think a lot of us, not just clinicians, are doing work for computers instead of the other way around. A focus on the workflow of clinicians would unlock significant benefits, through thinking about how can we help them do more of the parts of their work that are unique and spend less time on administration and data and all other things that create friction in their day. It would also lead to happier clinicians, and happier health service users. This is not about complex health technologies, it’s about doing the hard work of implementing solutions to make things work better.
Q: What opportunities can young professionals coming from data science and non-health related backgrounds expect in health technology, when it comes to skills that would be useful for the industry?
Babbage: In reference to health, it's really about drawing on the expertise from the people who have thought long and hard about these things—because if these were easy problems to solve they would’ve already been solved.
On the technology side, there’s an enormous amount that can be contributed, because people in the health system often aren’t technically savvy. But what’s really important to understand is what a technologist brings to a situation needs to still be focused on human behaviours as the primary question.
Build expertise in co-design, engaging with end users, and really understanding service-user perspectives and clinician perspectives. Understand why these end users might not be enthusiastic about your particular technology, and look at how it can actually make their life better, rather than harder. Thinking about what it would really mean for them to be using this in their practice as opposed to what do you think of my tool. If you can straddle those two worlds by bringing a technology background, you’ll be making a valuable contribution.
Reporter Anzel is interviewing Mr. Duncan Babbage
Author: Anzel Singh
Photographer: Victor Chateau
Editor: Christiane Zhao
Copyright By HTA.
Dr. Bertalan Mesko has published a new report, called "Digital Health Best Practices For Policy Makers". Healthcare in the 21st century is facing several challenges such as a growing demand for the management of chronic conditions and the increasing costs of healthcare. Digital technologies provide a pathway by which healthcare becomes sustainable and meets the most important goals: improving health, improving patient satisfaction and reducing costs. In the 21st century, this has significantly changed as pressure also comes from consumers who can access data, information and technologies. They don’t wait anymore for policy makers to make a technology available but turn to new technologies if that helps alleviate pain, better manage their disease or lead to a cure.
Health Technology in Canterbury
The Mayor of Canterbury, Winton Dalley, started the conference with an official regional report about Canterbury. He highlighted the urgent needs for technology to help solve health care access issues in the region’s deprived areas. New Zealand may be a country with particularly low population density and poorer public funding on health technology, but the good thing is that we can come together with the goal to benefit our population’s quality of life using improved health technology. The government states that high tech aggregate culture is significantly important, as well as high quality digital connectivities. Some of the part-time nurses in this district travelled thousands, and even millions, of kilometers annually to provide primary care in highly deprived and rural areas. Mobile health does not only help to deal with capital supply issues, but also helps to strengthen rural health services. Various technologies are currently publicised to be available, but are not affordable in high needs areas. Therefore, the challenges for Health IT professionals are to identify telehealth solutions to achieve equal access to care.
Technology applications in the current Healthcare market:
A photo taken in the "Emerging Tech in Health" Conference. The HTA CEO, Christiane Zhao(left) with the Mayor of Hurunui , Winton Dalley(right). Winton has been marked as one of the "most Influential Mayor" in New Zealand.
Event arranged by IAPPANZ & sponsored by Microsoft
GDPR is referred to as the General data Protection Regulation which widely covered organisations and companies offering goods and services to people in EU, or collecting and analysing data tied to the EU residents.
In short, there some key points in the regulations:
There are five rights which have been addressed:
The GDPR applies more broadly than many people think, each stakeholder should be aware of the impact this regulation could make on their daily practice.