Smart brain implants helping people with Parkinson's, other disorders
While performing one such surgery in 1987, French neurosurgeon
Alim-Louis Benabid
noticed that the electrical stimulation he performed to locate the right spot to lesion had effects similar to the lesion itself. This discovery led to a new treatment:
deep brain stimulation
. It involved a pacemaker delivering electrical pulses via electrodes implanted in specific spots in the brain.
This treatment has been used to treat advanced Parkinson's since the early 2000s. However, until today, the stimulator settings had to remain constant once they were set by a specialised doctor or nurse and could only be changed when the patient was next seen in the clinic.
Accordingly, most researchers and doctors thought of stimulation as merely an adjustable and reversible way of lesioning. But these days the field is undergoing a revolution that challenges this view.
Parkinson's is a complex disorder with fluctuating symptoms that are greatly affected by the drugs a patient takes several times a day. While for some patients constant stimulation does a good job controlling their symptoms, for others it is too strong some of the time and overly weak at other times.
Ideally, the treatment should only kick in when it is most helpful.
The discovery that made adaptive stimulation possible was made by scientists at
University College London
over two decades ago, around the time when the first patients with Parkinson's started getting electrodes implanted in the UK National Hospital for Neurology and Neurosurgery.
When recording deep brain activity from these electrodes shortly after the surgery, the scientists noticed that a particular kind of brain wave appeared when a patient stopped their medication and their symptoms worsened.
The waves went away when the patients took their medication and started feeling better. It took a decade of further research before the same team of scientists first attempted to use the brain waves to control stimulation.
The idea is akin to a thermostat controlling an air conditioner. When the waves (temperature) reach a certain threshold, an electronic control circuit turns the stimulator (airconditioner) on. This reduces the waves and when they go away the stimulation can be turned off for a while until the waves re-emerge.
The original setup was bulky and could only be used in the hospital, and it took another decade to make it fit inside a device smaller than a matchbox that could be implanted in a patient's chest.
New challenges
While the option to make brain stimulation adaptive gives new tools to doctors and nurses to fit stimulation to a patient in the best possible way, it comes with new challenges.
Even with the original fixed settings, there are many parameters doctors have to set to ensure effective treatment with minimal side-effects. Making stimulation adaptive adds another layer of complexity and puts extra demand on a clinical team's time and attention.
In the case of Parkinson's, stimulation effects are almost immediate so it is relatively easy to see how well particular constant settings work. But an adaptive setting must be tested over at least a few days to see how well it copes with the patient's daily routine and medication cycles.
Adaptive stimulators also come with sensing abilities. They can record the harmful brain wave levels over days and weeks so that the clinical team can review them and see how well they are controlled.
These possibilities are new in the treatment of Parkinson's, although similar implanted devices have been in use for years by cardiologists and epileptologists (neurologists who specialise in epilepsy).
Studying brain waves recorded by the smart stimulators in Parkinson's patients opens new doors for understanding other diseases. Many patients suffer from problems such as depression and cognitive decline. Researchers could search for features in their brain signals that track the severity of these symptoms using AI tools to find relations too subtle or too complex for a human observer.
A parallel branch of deep brain stimulation research is focused on precisely mapping out the brain circuits responsible for different neurological and psychiatric symptoms. Several recent studies reported successes in treating depression, OCD and severe headaches.
Stimulating in the right place at the right time considering what the patient is doing is where the field is heading. With the basic technology now in place, progress could be rapid.
(The Conversation)
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Indian Express
2 hours ago
- Indian Express
France battles rapid spread of viral cattle disease in cheese regions
France is battling the rapid spread among cows of an infectious illness called lumpy skin disease, with 51 outbreaks reported and about 1,000 animals culled since the first case was detected in late June, the farm ministry said on Thursday. A vaccination campaign launched on July 19 has so far covered around 100,000 cows in four Alpine departments, including Savoie and Haute-Savoie, where the outbreaks were detected, it said. Lumpy skin disease, a viral illness transmitted by insect bites, causes blisters and lowers milk production in cattle. It does not pose a risk to humans but often leads to trade bans and economic losses. A stage of the Tour de France cycling race was shortened last week after an outbreak along the planned route led to cattle culls and restricted access. The outbreaks have raised the alarm over the economic impact in regions known for production of cheeses such as Reblochon, Beaufort and Tomme de Savoie. 'We are in a growth phase of the disease,' a farm ministry official told reporters. France's national cattle herd numbers about 17 million, the largest in the European Union. Britain and other countries have banned imports of raw milk cheese from France due to the recent outbreaks, French dairy producers said. Lumpy skin disease is widespread in North Africa and was also detected in Italy in late June.
NDTV
a day ago
- NDTV
Dementia Takes 3.5 Years To Diagnose, Says Study; 9 Early Symptoms To Watch Out For
A new study has revealed that dementia diagnoses take an average of 3.5 years after symptoms are first noticed. The study, published in the International Journal of Geriatric Psychiatry, mentioned that the onset of dementia at a younger age and the presence of frontotemporal dementia were associated with a prolonged diagnostic period. Individuals with early-onset dementia may take an average of 4.1 years for a diagnosis, with certain groups being more prone to experiencing even longer delays. Importance of early diagnosis Dementia is a growing public health concern, affecting over 57 million people globally. Timely diagnosis of dementia helps individuals access timely treatment, preventing the symptoms from getting worse. "Timely diagnosis of dementia remains a major global challenge, shaped by a complex set of factors, and specific health care strategies are urgently needed to improve it," said lead author Dr. Vasiliki Orgeta, from the Division of Psychiatry at the University College London (UCL). Early signs and symptoms of dementia Understanding the signs and symptoms of dementia can help with timely diagnosis. For the unversed, dementia is a broad term used to describe a decline in cognitive function that affects a person's ability to remember, process information and speak, affecting the ability to engage in daily activities. Dementia typically causes memory loss, thinking difficulties, and behavioural changes. Alzheimer's disease is the most common type of dementia, followed by vascular dementia, Lewy body dementia, and frontotemporal dementia. Signs and symptoms: Dementia symptoms can vary due to the underlying cause. Early indicators can include issues with short-term memory and word finding. 1. Confusion Forgetting dates, seasons, or the passage of time, as well as losing track of where they are, can be a sign of dementia. 2. Memory loss Difficulty remembering recent events or new information is often one of the first symptoms. 3. Challenges with problem-solving Individuals with dementia may face difficulty in planning, organising, or solving problems. 4. Language difficulties Dementia can make it difficult to find the right words or follow conversations. 5. Changes in mood and personality Dementia can cause increased feelings of confusion, suspicion, depression, fear, or anxiety. This condition can also trigger frequent mood changes. 6. Difficulty with familiar tasks People with dementia may have trouble completing everyday activities, such as preparing meals or managing finances. 7. Visual and spatial difficulties Challenges in judging distances or determining colour can lead to problems with driving. 8. Loss of initiative A noticeable decrease in interest in previously enjoyed activities or social engagements is also a sign of dementia. 9. Repetition Someone with dementia may repeat conversations and questions obsessively. They may also repeat daily tasks. Recognising signs and symptoms of dementia early can significantly lead to timely intervention and improved quality of life.
Time of India
a day ago
- Time of India
Who is Audrey Crews? Paralysed woman writes her name after 20 years using Elon Musk's Neuralink brain chip
Source: X (Audrey Crews) In a groundbreaking medical and technological milestone, Audrey Crews, a woman paralysed for 20 years, has become the first Neuralink patient to publicly demonstrate thought-based computer control. With the help of a brain chip developed by Elon Musk 's Neuralink, Crews successfully moved a digital cursor and signed her name on a computer screen—using nothing but her thoughts. Her achievement, revealed through a viral social media post, not only showcases Neuralink's cutting-edge brain-computer interface (BCI) technology but also offers a glimpse into a future where individuals with paralysis may regain independence in ways previously unimaginable. Audrey Crews' achievement is more than a technological demonstration—it is a symbol of hope for millions living with paralysis. With Neuralink pushing boundaries, we are witnessing the early steps toward a future where physical disability does not limit a person's ability to connect, communicate, and create. Who is Audrey Crews and why is this moment historic Audrey Crews, also known as 'Patient P9' in Neuralink's clinical trial program, had lived with complete paralysis for two decades due to a severe spinal cord injury. Earlier this month, she underwent a brain chip implant procedure at the University of Miami Health Centre. Shortly after surgery, she shared an image on X (formerly Twitter) showing her digitally signed name with the caption: 'I tried writing my name for the first time in 20 years.' Her post quickly went viral and was confirmed by Elon Musk, who wrote: 'She is controlling the computer entirely by thought.' This demonstration represents a pivotal moment in medical neurotechnology, similar in significance to the first use of prosthetic limbs or cochlear implants. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like 11 Harry Potter Actors Who Grew Up Stunningly. The Noodle Box Read More Undo What is Neuralink and how does it work Founded in 2016 by Elon Musk, Neuralink is developing brain-computer interfaces (BCIs)—devices designed to establish a direct communication link between the human brain and external machines. Neuralink's three product goals: Telepathy – A BCI enabling individuals with physical disabilities to control computers and devices through neural signals. Blindsight – A vision restoration system bypassing damaged optic nerves by stimulating the brain's visual cortex. Deep – A neuromodulation platform aimed at managing conditions such as Parkinson's disease and epilepsy. By decoding brain signals and transmitting them wirelessly, these interfaces can allow paralyzed individuals to type, move robotic arms, operate wheelchairs, and potentially regain mobility. Neuralink has now implanted its device in at least five human participants, each showing the ability to control external systems purely through thought. How does the Neuralink brain chip function The Neuralink chip consists of ultra-thin electrode threads surgically implanted into specific regions of the brain responsible for motor control. Signal collection: The electrodes pick up electrical activity generated by neurons during movement intention. AI decoding: Advanced machine learning algorithms decode these neural signals in real time, identifying the user's intended action. Wireless transmission: The interpreted data is transmitted to a computer, where it translates into specific commands like moving a cursor, typing, or even controlling robotic limbs. In Audrey's case, this technology allowed her to move a digital cursor and write her signature—tasks she had been unable to perform for 20 years. Why is this a breakthrough for people with paralysis For individuals living with paralysis, everyday tasks such as writing, typing, or even using a smartphone become impossible without assistance. Neuralink's brain chip offers hope by bypassing damaged spinal cord pathways and directly linking thoughts to actions. Independence: Users can communicate, work, and interact with digital systems without physical movement. Rehabilitation potential: With future iterations, patients might control wheelchairs, exoskeletons, or prosthetic limbs. Medical insights: The data collected could deepen our understanding of neurological disorders and pave the way for targeted therapies. What's next for Neuralink The company is still in its early clinical trial phase, focusing on ensuring safety, reliability, and accuracy of its implants. The roadmap includes expanding to more patients and exploring applications beyond paralysis, such as restoring vision and treating neurological diseases. Elon Musk has emphasized that Neuralink aims to make brain-computer interfaces as common as LASIK eye surgery within the next decade. If successful, the implications for healthcare, human-machine interaction, and even general computing could be revolutionary. Also Read | Watch | Hawaii resident captures rare Tsunami siren after massive Russia earthquake: 'Never heard this in 11 years'
