Machine Learning Opportunities for Health

Read By 246 Members

“It can only be attributable to human error…” so said the HAL 9000 series computer from the movie 2001: A Space Odyssey. Of course, removing human error, where healthcare is concerned, would indeed be a remarkable achievement. A slightly more achievable goal, though, is to improve patient outcomes by augmenting clinical decision making with Machine Learning.

NHS England supports a patient population of over 54.3 million and employs around 1.2 million staff. In addition, when you consider the NHS treats well over one million people every 36 hours, or just over 500 patients a minute, it is obvious to many, that Machine Learning has a part to play in improving patient outcomes.

Machine Learning is a branch of the more commonly understood field of Artificial Intelligence, the preserve of many Hollywood ‘rise-of-the-machines’ dystopian movie story lines. In short Artificial Intelligence attempts to mimic human intelligence or behaviors while Machine Learning attempts to analyse, map and associate ‘patterns’ and ‘behaviors’ in multiple data sets to support intelligent, data-driven, decision making based on ‘new’ knowledge and understanding. It’s this ‘new’ knowledge that is the exciting part.

This ‘new’ knowledge can then be used to predict, for example, a patient’s diagnosis, course of treatment or even their level of risk with the added advantage of potentially reducing human error.

Given the obvious benefits, it’s well worth exploring the opportunities Machine Learning has to offer.

There are varying platforms to choose from with products such as Google’s DeepMind, IBM’s Watson and Amazon’s Machine Learning which all offer a suite of tools, models and analytics augmented by cool sounding descriptors such as creating ‘Neural Networks’ and implementing ‘Deep Learning’. Each differs in its approach, Google, for example, offers you access to open-source ‘hands-on’ software services like TensorFlow which provides a library for numerical computation using data flow graphs. Google uses TensorFlow for searching with their own Google Images and for predicting and creating auto-replies in Gmail.

Others, like Amazon’s Machine Learning, offer a more modular approach to guide you by making popular Machine Learning algorithms available to you such as analysing customer feedback or recommending products on retail websites. As always, the decision will be around how complex you need your computational models to be, and whether you have access to data scientists who can support the building and tailoring of the algorithms required. And behind the scenes, you will find bespoke ASIC (Application Specific Integrated Circuit) hardware processing designed to accelerate Machine Learning routines.

Google’s Tensor Processing Unit (TPU)

What are the opportunities for Health?

There are many areas where Machine Learning is already adding value. In the field of imaging and diagnostics, Machine Learning is being employed to search for patterns in images. Google’s DeepMind Health is running a project with Moorfields Eye Hospital NHS Foundation Trust and University College London Hospitals NHS Foundation Trust to analyse images and surface potential areas of concern and to offer a course of action based on its learning.

“Our algorithms interpret visual information in the form of de-personalised scans. The system is learning how to identify potential issues within these scans, and how to recommend the right course of action to a clinician” — Google DeepMind Health

Optical Coherence Tomography scan

Streams is another Machine Learning solution from Google DeepMind Health and to quote: ‘Streams is a secure instant alert app, addressing what clinicians call “failure to rescue”, when the right nurse or doctor doesn’t get to the right patient in time. Each year, many thousands of people in UK hospitals die preventably from conditions like sepsis and acute kidney injury, because the warning signs aren’t picked up and acted on in time.’

While the trial is ongoing the current evidence suggests that Nurses are saving 2 hours per day and patients with serious diseases are being seen more quickly, which is promising news for patients.

IBM Watson is also using Machine Learning for a number of projects including Drug resistant Tuberculosis in South Africa by analyzing drug susceptibility tests and TB genomes, each with 4.4 million base pairs. Another project is focused in the field of Neuroscience and is using images from multiple sources to find ‘neuromarkers of emotion’ that could improve Neurofeedback treatments.

Other key areas include the ability to predict treatments and assist with evidence-based medicine and reduce patient risk all based on Machine Learning using complex medical data.

Machine Learning for Clinical Trials

Machine Learning is also being used to assist in Clinical Trials. ScienceToday reports that Researchers at Cincinnati Children’s Hospital Medical Center are using Machine Learning to figure out why people accept or decline invitations to participate in clinical trials. Recruiting sufficient numbers of participants is a current challenge in medical research that can compromise results or stop some studies altogether.

In the study, 60 percent of patients approached with traditional recruitment practices agreed to participate. Researchers are predicting that their new automated algorithm could push acceptance levels up to about 72 percent.

Machine Learning is beginning to appear across Clinical Trials activity from recruitment to managing compliance and even the publication of the report.

Machine Learning and Cyber Security?

Machine Learning could also be used to improve NHS cyber security. Vendors such as Alert Logic are now turning to Machine Learning algorithms to detect security anomalies. Machine Learning can potentially ‘defend at scale’ by allowing a system to learn, and adapt to unusual activity on a national, or global scale, based on previous learnings and patterns of expected behaviour. The real value, as with all Machine Learning projects, is to discover ‘new knowledge’, in this case it could be a new type of malware or ransomware attack.

However this is still a maturing area with limitations. Interviewing security researchers one recent report notes that “there are too many high false positive rates, too much reliance on humans to make security decisions, slower security operations and “easy for attackers to bypass.” (Carbon Black the.report May 2017). Clearly, there is still work to be done before such Machine Learning based security tools are used without additional security layers, and humans supervising.

“At least for the next five years, a battle of “human vs. human,” where AI and ML can be used to augment and empower human reasoning, not replace it” Carbon Black the.report May 2017

Where next?

Machine Learning is already beginning to permeate every area of our digital life. In fact, you’re likely using Machine Learning almost every day without even knowing it. For example, Amazon’s Echo and Apple’s Siri use Machine Learning for speech recognition while Google’s image search uses Machine Learning to ‘understand’ the components that make up a picture. It does a pretty good job too, spawning the meme ‘Chihuahua or blueberry muffin?’ Feel free to ‘Google’ it.

While the HAL 9000 computer professed to be “by any practical definition of the words, foolproof and incapable of error” it will still be some time before humans would take an ‘unsupervised’ approach to decision making based on Machine Learning. However, there is no doubt that Machine Learning is already beginning to offer real-world value. It’s almost certain, that in the near future, all medical diagnostics, monitoring and treatment plans will, in-part, come from knowledge derived from, and recommended by, Machine Learning platforms.

Gareth Baxendale FBCS CITP

Head of Technology NIHR Clinical Research Network.

Vice Chair BCS Health and Care Executive

TheDigitalBrief.com

@TheDigitalBrief

Read By 246 Members

Gareth Baxendale FBCS CITP

...a boffin armed with a swimming certificate. Having achieved my long sort-after swimming certificate by age 7 (a proud day), I went on to gain yet more learning, experience and wisdom... oddly, swimming as a skill has not been a requirement of any of my roles to date... I remain hopeful. Despite my dashing young looks, I have 20 years in B2B, B2C and Health developing strategy, designing and architecting IT solutions, both locally and cloud based, as well as managing the supply of doughnuts and coffee to large development, infrastructure and service delivery teams. Few headlines... • • FBCS CITP Chartered Fellow • • Vice Chair for the BCS Health Executive focusing on improving Health Informatics across the health sector • • Writer for The Guardian, Wired.com, Computing.co.uk, ITNow, DigitalHealth, Section Editor Journal of Innovation in Health Informatics • • Medalist UK IT Industry Awards 'IT Department of the Year'​ - Computing/BCS • • Team achieved NCC ITDA Accreditation standard • • BCS Chartered Assessor & Mentor • • SFIA® Framework Reviewer • • UKCHIP Level 3 Health Informatics • • TOGAF® 9 Level 2 Enterprise Architecture • • ITIL® Expert Service Management • • PRINCE2 Certified • • Microsoft Certified Engineer/Architect levels I currently work for the National Institute for Health Research managing the Information Services and Service Delivery function that enables IT services for the NHS Clinical Research Network. With a key focus on Informatics and clinical trial adoption we support over 10,000 users in the NHS and Industry Pharma. I lead the devops/service management teams and am responsible for the technology architecture, design and delivery both locally and for cloud services with Amazon Web Services working alongside our partner PA Consulting. Previously I have supported B2B B2C IT companies from SME's to NASDAQ enterprises, and also in the mutual sector managing IT for a large healthcare organisation supporting over 900,000 members.

Have Your Say: