Actual Audio: You want to go into superior colliculus a bit more?
Transcription Software: You want to go into the spiritual leaders a bit more.
Audio: So the input is converging.
Software: So the imprint is converging
Actual Audio: You want to go into superior colliculus a bit more?
Transcription Software: You want to go into the spiritual leaders a bit more.
Audio: So the input is converging.
Software: So the imprint is converging
In PlainSpeak for Lay Audience
Disability and Poverty: A Tough Cycle
Disability and poverty are closely connected. This makes life harder for disabled people. Here’s why.
Education: Many disabled people don’t get a good education. This makes it hard for them to learn skills needed for good jobs.
Jobs: Disabled people often face problems finding jobs. There aren’t enough job opportunities, and some employers discriminate against them. Without good jobs, it’s hard to earn enough money.
Healthcare: Poor people often can’t afford good healthcare. This can lead to untreated health problems that cause or worsen disabilities.
Support Services: Disabled people need special support, like assistive devices or home modifications, but these can be expensive. Without money, they can’t get the help they need.
The National Council on Disability says that these problems make more disabled people live in poverty. The World Health Organization also says that we need to solve both poverty and disability issues together.
To break this cycle, we need to:
When we invest in these areas, we help disabled people live better lives. This also helps reduce poverty and builds a stronger, fairer society for everyone.
2 versions of this post
The False Moral Authority of Titles
A PlainSpeak version for the Lay Reader
The Role of Parvalbumin Neurons in Autism
Scientists believe that a special type of brain cell called Parvalbumin (PV) interneurons (INs) may play a key role in autism. Even though autism can be caused by many different genetic and environmental factors, people with autism often show similar behaviors. This suggests that there might be a common issue in the brain across different individuals with autism (1).
Understanding the role of PV+ interneurons in autism helps us see why many symptoms of autism occur, like sensory sensitivity and seizures.
Our brains need a balance between "go" signals (excitation) and "stop" signals (inhibition) to work properly. In autism, it was first thought that there is too much excitation and not enough inhibition, leading to an imbalance. This imbalance could explain why some people with autism have seizures (4,5). However, this idea is too simple because many types of brain cells are involved in maintaining this balance.
Researchers have found that PV+ cells in the brains of autistics are often not working as they should:
PV+ cells are the most common type of inhibitory ("stop/slow down") neuron in the brain, but other types of neurons may also be involved in autism.
When PV+ cells don't function properly, the brain becomes overly excitable and synchronized, making seizures more likely. This can also cause exaggerated responses to sensory inputs, like touch or sound. For example, in a mouse model of autism, the response to whisker movement is weaker in certain brain cells.
Autistics often experience sensory overload because their brains can't tune out irrelevant information. This may be due to a failure of brain cells to adapt to continuous stimulation (2).
PV+ neurons are important for fine-tuning the way we see things, helping us to distinguish between different visual inputs.
Increased gamma wave activity, which is linked to sensory and communication issues, is common in autism. PV+ cells help generate these waves, and their dysfunction leads to irregular brain activity patterns (3).
2 Versions of this Post
For the Science/Academic Reader
The E-I Imbalance hypothesis posits that an imbalance between excitatory and inhibitory signaling in the brain contributes to the sensory, cognitive, and behavioral features of autism.
PlainSpeak: This idea says that a mix-up between signals that excite and calm the brain can cause the sensory, thinking, and behavior issues in autism.
When we talk about autism, two important ideas often come up: monotropism and special interests. These ideas help explain how autistic people focus on things they love, but they mean slightly different things.
Monotropism is a way of thinking that means autistic people tend to focus really hard on a few things at a time. Imagine being able to dive deeply into something you’re really interested in, like a favorite hobby or subject. This can make autistic people very knowledgeable and passionate about their interests. But it can also make it tough to switch focus to other things they find less interesting.
Special Interests are those specific things that autistic people get really excited about. These can be anything from dinosaurs to trains, from art to computers. These interests often last for a long time and can bring a lot of joy and comfort. They’re a big part of who they are. Sometimes, though, other people might not understand why these interests are so important to them.
So, what’s the difference? Monotropism is about the way autistic people focus their attention, while special interests are the actual things they focus on.
Scientists think that the way autistic brains work makes this deep focus possible. It’s not just a quirky behavior – it’s how their brains process information. This means autistic people often put a lot of mental energy into their favorite things, which can make it hard to deal with tasks they don’t enjoy as much.
By understanding monotropism and special interests, we can better support autistic people. We can appreciate their focus and passion while also helping them with strategies to manage tasks they find challenging.
Two Versions of this post
My research abstract accepted at Society for Neuroscience, SfN 2024 conference.