Tag Archives: brain

The Basics of Alzheimer’s Disease

Today is World Alzheimer’s Day, a day to raise awareness for a disease that is likely to affect 1 million people in the UK by the year 2025. To mark the day, our Social Media Intern and Neuroscience student, Charlie Wilkinson has written a guest post for us:

Alzheimer’s disease is a devastating neurodegenerative condition involving the death of nerve cells (neurones) in the brain, and the subsequent break down of communication between synapses.

Affecting millions worldwide, Alzheimer’s Disease is the most common form of dementia in the elderly, affecting 850,000 people in the UK alone. The disease is associated with serious cognitive decline, including typical memory and language impairment. The disease has now overtaken heart disease as the leading cause of death in women.

The biological mechanisms that underpin the development of Alzheimer’s Disease can be boiled down to the formation of plaques, and tangles. The development of the condition is a result of faulty mechanisms in the brain for the breakdown of a specific protein.

Plaques 

Amyloid Precursor Protein (APP)  is a protein found abundantly in the brain, stuck in the membranes of neurones. The function of the protein is largely unknown, but the way this protein is broken down is the critical early event in Alzheimer’s Disease.

Proteins like APP are made up of many small units known as amino acids; enzymes have the ability to break down proteins by cutting at specific amino acid sites. If the APP protein is cut by one enzyme (alpha), the protein that’s formed is healthy and soluble. If however, APP is cleaved by another enzyme (beta), the protein that’s formed is diseased and insoluble. This diseased protein is known as beta-amyloid.

As more of this beta-amyloid protein is formed, the proteins start to stick together or aggregate, forming senile plaques. Although the way these plaques cause damage isn’t fully understood, it is theorised that the body reacting to the plaques with an inflammatory response leads to damage of neuronal cells in the brain, which is the typical symptom of Alzheimer’s Disease.

Tangles

The other proteins typically associated with Alzheimer’s Disease are neurofibrillary tangles. Tangles are formed through twisted fibres, formed as small protein units called ‘tau’ which stick together inside neurones.

The tau proteins are usually associated with the transport system inside these cells – nutrients are important for the function of these nerve cells, and transport systems supported by tau are important in moving nutrient and other supplies around the cell.

When tangles form using tau proteins, these transport systems essentially malfunction meaning nutrients and other essential products can’t be transported around the cell and the cell starts to die.

There is no cure for Alzheimer’s Disease, and treatments can only target the cognitive decline and other symptoms associated with the disease. Treatments for the condition, however, are becoming ever more effective targeting different aspects of the disease. The determination of researchers to develop treatments to reduce the burden of the disease in sufferers, is encouraging for the future of Alzheimer’s disease.

The 21st September 2017 is world Alzheimer’s day. For more information about Alzheimer’s Disease and to find out how you can help combat this illness visit the Alzheimer’s Society here.

 

Ten Amazing Facts about the human body!

You take it everywhere you go, but I bet that there are a few facts about your body that you didn’t know!

1. There is enough DNA in the human body to stretch from the Sun to Pluto and back – 17 times! 

There are about 37 trillion cells in the human body, all of them containing about 5cm of of DNA (when uncoiled). DNA is made up of lots of different nucleotide pairs that can decide some of our features such as eye and hair colour.

2. The average human body contains ten times more bacterial cells than human cells.

However bacteria are much smaller so don’t take up that much space. Lots of these bacterial cells are important, such as intestinal bacteria that help keep our immune systems healthy.unravelled-dna

3. Except for identical twins, each person on Earth has a unique smell.

Just how we each have individual finger prints we all have our own smell. This is determined by your genes, and can be used by other animals to identify individuals.

4. An individual blood cell takes about 60 seconds to make a complete circuit of the body. 

The average heart pumps about 70ml of blood out with each beat and a healthy heart beats around 70 times a minute.

5. By the time you go to bed at night you are about 1 cm shorter than when you woke up that morning.

This is because the cartilage between your bones is compressed throughout the day.

6. Nerve impulses to and from the brain can travel as fast as 250 miles per hour. 

A nerve impulse is an electrical signal that sends messages to the brain when the nerve is triggered by a stimulus. It is really important that they travel fast, for example, if you burn your finger it’s important that your brain gets the message to stop touching it quickly.nerves

7. There are as many hairs per square inch on your body as a chimpanzee.

Humans are not quite the naked apes that we’re made out to be. We have lots of hair, but on most of us it’s not obvious as a majority of the hairs are too fine or light to be seen.

8. The human body is estimated to have 60,000 miles of blood vessels.

To put that in perspective, the distance around the earth is about 25,000 miles, so your blood vessels could travel more than two times around the Earth if laid out.blood-vessels

9. Babies are always born with blue eyes.

The colour of your eyes depends on the genes you get from your parents, but at birth most babies appear to have blue eyes. The reason behind this is the pigment melanin. The melanin in a newborn’s eyes often needs time after birth to be fully deposited or to be darkened by exposure to ultraviolet light, later revealing the baby’s true eye colour.

10. Every day an adult body produces 300 billion new cells.

Your body not only needs energy to keep your organs up and running but also to constantly repair and build new cells to form the building blocks of your body itself.

#TryThisTuesday: Valentine’s Day Optical Illusion

Happy Valentine’s Day! Love can confuse your brain, and so does this week’s Try This Tuesday.

You don’t need any equipment to try this experiment at home – you just need to stare at your screen, or more specifically the + in the middle of the picture below. You can blink but don’t look away.

heart-optical-illusion

If you stare long enough the pink dots should disappear!

The Science

It looks like the pink dots have disappeared due to a visual phenomenon called Troxler’s fading or Troxler’s effect. if you fix your eyes on a certain point, then anything in your peripheral vision will fade away and disappear after about 20 seconds. In this experiment our sight was focused on the + in the middle of the screen and the the pink dots in your periphery slowly fade and finally disappear. It works especially well in this experiment at there is such low contrast between the light pink dots and the grey background.

This is a type of optical illusion. If you want to see another, have a look at our spinning disk Try This Tuesday.

 

#TryThisTuesday: Spinning Disk

This Tuesday, you don’t need any equipment to try this experiment at home – you just need to stare at your screen, or more specifically the video clip below:

(don’t worry we aren’t trying to hypnotise you!)

Stare in the dot in the middle of the circle for 20 seconds, you can blink but don’t look away, keep your eyes focused there. After 20 seconds look at someone’s face, if there’s no one around you, get a face up on screen that you can quickly look at.

What did you see?

Hopefully, if it worked you should have seen the face appearing to get bigger. Obviously, it didn’t really grow before your eyes, this is simply an optical illusion playing a trick on your brain.

You see things because your eyes send messages to your brain about different types of light, shapes and movement and your brain makes up an image of the world around you. When you stare at the spinning disk for so long, your eyes continually send messages to you brain to say its spinning. Your brain gets a bit bored of hearing the same message over and over again so kind of stops listening, tunes out the messages and just assumes from now on, this is how it is – everything is spinning.

So when you look away at a face or your hands or anything really, your brain thinks it should be spinning so gets confused and spins the image in the opposite direction, making it appear to grow. After a few seconds, your brain will hopefully catch up and everything will go back to normal.

The Chemistry of Being Scared

Happy Halloween! We all like being scared sometimes, whether it’s scary movies or a rollercoaster, but why do we get scared?

We feel fear when we see or hear something that makes us anticipate harm. If you are walking through a haunted house this Halloween and a skeleton jumps out at you, the skeleton is a stimulus that triggers a signal in your brain.

The hypothalamus is part of your brain that activates the ‘fight or flight’ response. When you are scared molecules of glutamate (a neurotransmitter) travel to the hypothalamus. This then triggers the autonomic nervous system, a response that you can’t control.

brain

Nerves from the brain carry impulses to glands which produce adrenaline, released into the blood. Adrenaline causes our heart rate and blood pressure to increase making us ready to run away quickly.

When we get scared we also get goosebumps. This is a trait that evolved in our hairier ancestors. When our hair stands up on end it makes us look bigger and more threatening to whoever is scaring us. This is seen in other animals too, such as cats.

However, we aren’t scared forever. Eventually our body realises that there is nothing to be worried about.  Sensory data of what we have seen and heard is sent to the hippocampus in the brain which can store and retrieve conscious memories. It gives context to what we have seen and asks questions such as have I seen this before and what happened last time?

If a skeleton jumps out, we will realise that it isn’t real and is probably just someone dressed up! The hippocampus will determine that there is no danger and sends a message to the hypothalamus. Adrenaline production stops and our heart rate goes back to normal.

thinking

We have evolved to feel fear to allow us to survive. People and animals who feared the right things survived and passed on their genes. This makes sure we don’t do stupid things like picking up poisonous snakes or walking off buildings.

halloween