Daily Protein Science

Weight‑loss drugs like Ozempic could work for addiction too – and we finally know how

For many people, the thought of a tasty burger or a cold pint of beer conjures up a vivid mental image and drives behaviour.

This link between thinking and doing serves a clear function – it motivates us to get the necessities for life.

But for some, this process can malfunction. Preoccupation with these rewarding stimuli can lead to disorders of substance overuse, including overeating to the point of obesity and alcohol abuse.

Studies going back to the 1970s have linked vivid mental imagery with drug abuse.

Understanding this link between craving and consuming is central to understanding addiction. This has eluded neuroscience for decades, but the introduction of a new class of drugs for weight loss may have given us just the lever we need to understand it.

These new drugs – including Ozempic and Wegovy – mimic the GLP-1 hormone to stimulate insulin release, slow digestion, and increase feelings of fullness. They are known as GLP-1 agonists and were originally used to treat type 2 diabetes because they help control blood sugar.

As a side effect, people using these drugs also lost a lot of weight, in some cases almost as much as might be expected from bariatric surgery.

But there is another less well publicised effect. Human studies show that GLP-1 agonists reduce alcohol consumption. Preclinical animal studies suggest these drugs also reduce the use of cocaine, amphetamines, opiates and nicotine.

These drugs are changing how we think about the brain’s reward system. They may also open new treatment options for obesity, alcohol dependence and the consumption of other addictive substances.

How the brain regulates reward stimuli

We have a reasonable understanding of the brain’s “reward circuitry” associated with regions that produce the neurotransmitter dopamine.

These brain parts – the ventral tegmental area (VTA) and nucleus accumbens (NAc) – have been the subject of research on reward for decades. They are the obvious candidate regions to look for a mechanism for GLP-1 action in the brain. But they lack significant density of receptors for GLP-1 and are unlikely to be the direct mechanism.

We must, therefore, consider other brain regions to understand the anti-consumption effect of GLP-1 drugs.

One jump “upstream” from the dopamine-producing brain parts is a region called the lateral septum. This brain structure has been historically implicated in emotional regulation.

Back in 1953, pioneering US behavioural researchers Joseph Brady and Walle Nauta coined the term “septal rage” when animals with damage in the lateral septum showed increased aggression, while direct stimulation of this brain region reduced aggression.

Much more recent work has placed the lateral septum at the centre of a neural connectivity network. This has reframed how we think about its function.

While a link between the lateral septum and another region called the hypothalamus is probably responsible for septal rage, the lateral septum links with many other regions with various functions.

The brain’s reward control centre

The lateral septum inherits much of its primary input from a brain region called the hippocampus.

This region is well known as the place that lets us form long-term “episodic memories”. A famous case of hippocampal damage, Henry Molaison (patient HM), was unable to form new memories after his surgery for epilepsy. He effectively lived without a past, in permanent present tense.

The hippocampus also contains the remarkable “place cells” – neurons that fire corresponding to a person’s thoughts about their position in space and, as recent research has shown, time.

This “where and when am I” information gets forwarded to the lateral septum. Key research has recently shown the lateral septum also contains place cells, but these cells strongly respond to rewards. They effectively add “what is good in this place” to the “where and when am I” information from the hippocampus.

Critically, the lateral septum shares this information with the dopamine-producing regions we would normally associate with reward.

Neuroscientists now think of the lateral septum as the brain region that lets us “think about” rewards – our conscious perception of them – and communicates with the machinery in the brain’s reward system that produces dopamine to make us feel good about them.

There is one last reason to suspect the lateral septum as the mechanism behind the anti-consumption effect of GLP-1 agonists. It is absolutely loaded with GLP-1 receptors.

Emerging research points to this as the mechanism. GLP-1 activation directly in the lateral septum has recently been shown to reduce food consumption in mice. Earlier this year, another study showed the same for alcohol consumption.

My own lab has shown this year that GLP-1 drugs reduce a type of activity in the lateral septum that may prevent it communicating so effectively with other brain regions.

These findings are reshaping our understanding of how the brain processes rewards and have put the spotlight firmly on the lateral septum as the home of cravings.

Robert Munn, Senior Lecturer, University of Otago

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Read More........→June 22, 2026 Categories: Health

Want to be a citizen scientist? Here are 5 ways to get involved

Elodie Camprasse, CC BY-ND

Miki Perkins, The Conversation

Ever wondered what it might feel like to spot giant spider crabs while you’re snorkelling? Or check plants for the circular holes that indicate native bees are collecting nest materials?

Citizen science relies on people like you – more than a million of them in Australia, actually – to collect and analyse valuable data about the world around us.

Here, we introduce five citizen science projects you can take part in. For most of them, all you need to get started is an app on your phone.

Science lives far beyond the lab, and it’s not just done by scientists.

In this series, we spotlight the world of citizen science – its benefits, discoveries and how you can participate.

Spider Crab Watch

Elodie Camprasse, Honorary Fellow – School of Life and Environmental Sciences – Deakin University

Every winter in Port Phillip Bay in Naarm/Melbourne, tens of thousands of great spider crabs gather in shallow water to moult – shedding their shells and growing new ones that grow to about 16 centimetres. But scientists know surprisingly little about them. The gatherings can be unpredictable and short-lived, making them difficult for scientists to monitor alone.

Spider Crab Watch helps researchers fill these knowledge gaps. By bringing together observations from the public – including divers, snorkellers and fishers – scientists can better understand when and where gatherings occur, how long they last, and what environmental conditions might trigger them.

Citizen scientists have already logged hundreds of observations, helping researchers identify new gathering sites and better understand when aggregations occur. Participants can log when and where they see spider crabs – whether a single crab or a large group, in Port Phillip Bay or elsewhere. Photos are helpful but not essential. Empty shells washed up on beaches can also be logged.

Gatherings of great spider crabs can be fleeting and in different locations. Elodie Camprasse, CC BY-ND

NOBURN

Sam Van Holsbeeck, Research Fellow – Forest Research Institute – University of the Sunshine Coast

NOBURN (the National Bushfire Resilience Network) is a citizen science project aimed at improving our understanding of the role of vegetation in bushfire risk. Using an app, people around Australia can log their observations – including site photographs – to support research into fuel dynamics, fuel load and bushfire risk.

Guided by the app, participants assess vegetation at a site, noting factors such as shrub density and overall fuel hazard. Observations typically take 10–15 minutes and can be conducted by community members, landholders, students or land managers. To date, we have collected 154 verified site observations and more than 160 registered users.

Observations supplied by citizen scientists help researchers understand the structure, density and dryness of forest fuels. Combined with AI, this data allows for better prediction of the likelihood and severity of fires. While this data is not as detailed as a full expert assessment, they provide useful indicative information, particularly in areas where formal fuel monitoring is limited.

FrogID

Jodi Rowley, Curator – Amphibian & Reptile Conservation Biology – Australian Museum – UNSW Sydney

Australia’s frogs are in trouble. At least four species have been lost and dozens more are on the edge of extinction. Yet we lack the information needed to make informed decisions about how to conserve them. Frogs are very sensitive to environmental change. This makes them great indicators of environmental change (they’re often referred to as the “canary in the coal mine”). By monitoring them, we also gain insight into environmental health.

FrogID taps the keen eyes and ears of people across Australia to gather the data needed to help save Australia’s frogs.

Using our free app, people can record frogs wherever they hear them. The best time is after rain and in the first few hours after dark. Once submitted, Australian Museum frog experts listen to the recordings and identify species.

There are more than 100,000 registered users of FrogID who have together gathered almost 1.5 million records of frogs from across Australia. It’s safe to say this dataset has revolutionised our understanding of frogs in Australia – including finding 13 frog species new to science.

1 Million Turtles

James Van Dyke, Associate Professor in Biomedical Sciences – La Trobe University

Freshwater turtle numbers have fallen 60–90% across most of the rivers and wetlands of Australia, amid engineered flows and increasingly dry conditions. As turtles disappear, they leave a large gap. Turtles are the “vacuum cleaners” of the waterways, eating decaying organisms and vegetation and improving water quality.

The 1 Million Turtles project aims to increase survival rates of freshwater turtles and turtle nests, and increase Australia’s turtle population by at least one million animals.

People of all ages can download and record any turtles or turtle nests they see in Australia. They can also volunteer for other activities, such as nest protection, via our website.

To date, our citizen scientists have logged nearly 34,000 turtle records across the country. They have also saved more than 2,600 turtles from dangerous road crossings, and protected more than 1,940 turtle nests from invasive foxes and pigs.

Assuming each nest held an average of 15 eggs, and half of the turtles saved on roads were adult females of reproductive age, our program has given 400,000 turtles the chance of a future in just the past five years.

Data from this community conservation program has led to the conservation status of turtle species being upgraded to threatened or endangered. It has also prompted the development of state conservation programs for turtles in New South Wales, Victoria and South Australia.

A broadshell turtle. Turtles are the ‘vacuum cleaners’ of the waterways, eating decaying organisms and vegetation and improving water quality. James Van Dyke, CC BY-ND

Australian ‘leafcutter’ bees

Kit Prendergast, Research Fellow – School of Science – University of Southern Queensland

Native bee numbers are declining and we have limited information about them. There are more than 2,000 species of native bee, including the Megachile bee. Some species of Megachile bee use plant leaves or even petals to build their nests, giving them the common name of leafcutter bees.

We don’t yet know which plants these bee species rely on. This citizen science project allows the public to use an app to identify which plants the bees are relying on. By noting preferred plants, we’ll have a better idea of how to create habitats for these gorgeous native bees and pollinators.

Most native bees cannot be identified by citizens, due to the specialised skills required, and most diagnostic features being microscopic. But when it comes to plants, these are much better known among the public and can be identified easily by photos.

Members of the public can download the free iNaturalist app and when they see a plant that has distinctive discs cut out, or see a Megachile bee in action, they can take a photo of the leaf “damage”. Once completed, gardeners, land managers and farmers will be able to access an evidence-based list of which nesting plants should accompany food plants.