Healthcare

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A study using real-world health questions found that healthcare professionals preferred AI responses to those of physicians 79% of the time, citing higher quality and empathy. | SciTechDaily




Generative AI in Healthcare



ChatGPT in Healthcare

ChatGPT in Home Health



First human to be able to live past 150 'has already been born', scientists claim | David Sinclair - Harvard Medical School]


Benefits of AI in Healthcare

AI Innovations in Healthcare

Focus

Dementia


Dementia Prevention

Alzheimer’s Disease Detection

Parkinson’s Disease Detection

Respiratory Disease Detection

Pneumonia Detection

Tuberculosis Detection

Heart Disease Detection


AI Stethoscope

In a groundbreaking initiative, London's Golborne Medical Centre welcomed an AI stethoscope in the UK’s first deployment of the technology in primary care. The tool has been licensed by medical regulators for use by general physicians. Interestingly, it will be the very first AI product that can be relied on to prescribe life-saving medication without the need for a specialist review first. What’s special about this stethoscope? This innovative stethoscope, developed by Mayo Clinic spin-off Eko, mirrors the familiar design of traditional ones but comes with a crucial twist – it utilizes artificial intelligence to instantly detect heart disease. The development is particularly significant for Golborne, where nearly half of the patients hail from non-white minority ethnic groups facing a higher risk of heart disease-related fatalities. The primary goal of the AI stethoscope is to bridge existing healthcare gaps, ultimately saving lives by providing early treatment to heart patients while they await further care. Experts anticipate that the prevalence of heart disease in the UK may be double the reported figures, highlighting the urgency of such advanced diagnostic tools. AI stethoscope shocks doctors OpenTools


Eyes / Vision

Hearing

Recent advances in AI have enabled machines to achieve human-like performance in important hearing-related tasks such as Automatic Speech Recognition (ASR) and Natural Language Processing (NLP). Essentially, Deep Learning allows hearing aids to begin to mimic how your brain would hear sound if your hearing wasn’t impaired. AI can be applied to hearing aids to improve their functionality. For instance, AI can help hearing aids function better in challenging situations such as engaging in a conversation when you’re in a crowded, loud space (think: a restaurant or cafe). AI can help hearing aids automatically dampen the sound of background noise and focus on amplifying speech instead.

AI has the potential to transform hearing healthcare and research. In addition to improving the functionality of hearing aids, AI can also be applied to advancing research and developing new therapies to meet the growing global demand for hearing care. For example, AI can be used to improve the diagnosis and treatment of many common conditions and more effectively deliver hearing care worldwide. AI can also be used to develop new tools for hearing research, such as computational models that faithfully model the auditory system. Example devices:

  • Widex Moment:
    • Product Information: AI and machine learning to create personalized hearing programs. Direct streaming to both Android and iOS devices. Choice between rechargeable and disposable battery-powered models.
    • AI Methods: AI and machine learning.
    • Unique Capabilities: Personalized hearing programs.
    • Pricing: $2,268 - $5,400.
  • Starkey Livio Edge AI:
    • Product Information: AI to provide instant adjustments for challenging listening situations. Features such as activity tracking, brain engagement tracking, fall detection, translation, transcription, and more. Rechargeable option with lithium-ion battery technology. Bluetooth connectivity to iOS and select Android devices.
    • AI Methods: AI.
    • Unique Capabilities: Instant adjustments for challenging listening situations.
    • Pricing: $4,000 - $7,000.
  • Oticon Real:
    • Product Information: AI to process sound more like the brain does - uses AI in the form of an on-board Deep Neural Network (DNN) that is trained with 12 million real-life sound scenes. This DNN makes sounds more distinct and works seamlessly across varying listening environments. The DNN recognizes all types of sounds, how they should ideally sound, and instantly adapts to changes, helping you remain focused, engaged and sharp. Bluetooth connectivity to iOS and select Android devices.
    • AI Methods: Deep Neural Network (DNN).
    • Unique Capabilities: Processes sound more like the brain does.
    • Pricing: ~ $4800.


Language Translation

`Livio AI` by Starkey Hearing Technologies that can enable real-time language translation. Livio AI is the first multi-purpose hearing device that not only sounds better than other hearing aids out there, it also lets you track your brain and body health, stream music, phone calls and more from your smartphone, and translate languages as you hear them. It can translate 27 languages as you hear them.

Cancer Detection

Imaging

Neuroradiology

Brain and Spine

Gert-Jan Oskam was living in China in 2011 when he had a motorcycle accident and was paralyzed from the hips down. But with a combination of devices, scientists were able to provide a “digital bridge” between the man’s brain and spinal cord. It allowed him to stand, walk, climb a steep ramp with a walker, get in and out of a car, and even stand at a bar for a drink. More than a year after the implant, he retained these abilities and actually showed signs of neurological recovery, walking with crutches even when the implant was turned off.

  • A brain-computer interface was implanted above the part of the brain that controls leg movement
  • The interface uses algorithms based on AI methods to decode brain recordings in real time

Ontologies

Machine Learning Examples - Siraj Raval

Transforming Medical Education and Training

Cost Estimation

Patient Care

Healing

Robots for Healthcare

Explainable AI for Healthcare

Gut-Brain Axis (GBA)

The gut-brain axis (GBA) is a network of nerves that connects the brain and gut, allowing for two-way biochemical signaling between the central nervous system (CNS) and the gastrointestinal tract. The GBA includes anatomical, endocrine, humoral, metabolic, and immune routes of communication. The GBA allows the brain to influence intestinal activities, and gut microbiota can affect the GBA in several ways:

  • Endocrine pathway: Gut microbiota can alter nutrient availability, which can affect the release of biologically active peptides from enteroendocrine cells.
  • Neuroactive substances: Gut microbiota can produce neuroactive substances that may influence the core symptoms of neuropsychiatric disorders.

Millions of nerves and neurons run between the gut and brain, and neurotransmitters and other chemicals produced in the gut also affect the brain. For example, stress-induced stimulation of the gut-brain axis can cause symptom flare-ups in irritable bowel syndrome (IBS). Improving gut health may benefit the gut-brain axis. Omega-3 fatty acids, fermented foods, probiotics, and other polyphenol-rich foods may improve gut health.

Enteric glia

are a unique class of peripheral glial cells within the gastrointestinal tract, primarily found in the enteric ganglia of the myenteric and submucosal plexuses of the enteric nervous system (ENS). These cells play a crucial role in regulating gut functions, including motility, immune responses, and maintaining the integrity of the intestinal epithelial barrier. Despite the potential, there are several gaps in our current understanding of enteric glia that need to be addressed. For instance, the exact mechanisms by which enteric glia interact with other cell types in the gut and their role in various diseases are still not fully understood While there is no specific mention of AI being currently applied to the study of enteric glia in the provided sources, the potential for AI to revolutionize this field is significant. Future research should focus on these areas, and integrating AI could provide the tools needed to make significant advancements. Here are some ways AI could be utilized:

  • Data Analysis and Pattern Recognition: AI can be used to analyze large datasets from genomic, proteomic, and metabolomic studies to identify patterns and correlations that might be missed by traditional analysis methods. This could help in understanding the complex interactions between enteric glia and other cell types in the gut.
  • Predictive Modeling: Machine learning algorithms could be developed to predict the outcomes of various treatments on enteric glia function and gut health. This could be particularly useful in developing new therapies for conditions like inflammatory bowel disease (IBD) and Crohn's disease, where enteric glia play a significant role.
  • Imaging and Diagnostics: AI-powered imaging techniques could enhance the visualization of enteric glia in the gut, allowing for more precise diagnostics and monitoring of diseases. Advanced image analysis could help in identifying subtle changes in glial cell morphology and function that are indicative of disease.
  • Drug Discovery and Development: AI can accelerate the drug discovery process by predicting how new compounds will interact with enteric glia. This could lead to the development of targeted therapies that modulate glial function to treat gastrointestinal disorders.


Blockchain, AI and Healthcare

Python for Healthcare