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Mum fined for pumping breast milk in the car

<p dir="ltr">A mum from Queensland has received a hefty fine for something she has done many times before. </p> <p dir="ltr">Meagan Schmock and her husband Benjamin were travelling home from their honeymoon on the Gold Coast when Meagan, who is a breastfeeding mum, started to feel unwell. </p> <p dir="ltr">"I was getting quite engorged and it was getting incredibly uncomfortable for me. It's throbbing, it's hot," Mrs Schmock told <a href="https://9now.nine.com.au/a-current-affair/queensland-mum-fined-after-pumping-breast-milk-in-passenger-seat/e2a4be4a-7201-43df-896c-ddbff34acee8" target="_blank" rel="noopener"><em>A Current Affair</em></a>.</p> <p dir="ltr">Meagan was in the passenger seat while her husband drove, so Meagan was able to pump breast milk for her 10-month-old son Billy. </p> <p dir="ltr">"To have to sit in the car for an hour-and-a-half, maybe two hours, waiting to get home to feed my little one, It just wasn't going to happen," Mrs Schmock said.</p> <p dir="ltr">While pumping, traffic cameras snapped a picture of the mum adjusting herself for a split second, resulting in a fine. </p> <p dir="ltr">"They have captured me taking my seatbelt off, putting it underneath my arm so I can unhook my breast pump," she said.</p> <p dir="ltr">Mrs Schmock said her seatbelt remained fastened the whole time and only slipped under her armpit for a split second.</p> <p dir="ltr">However, the manoeuver has now landed her husband a hefty infringement notice for driving with a passenger who failed to wear their seatbelt correctly.</p> <p dir="ltr">"It was $1161 and four demerit points. I was gob-smacked. I was shocked," Mrs Schmock said.</p> <p dir="ltr">"I saw the money fine first and I was just like, 'what's happened'? And then as I've unfolded the letter, I've seen this photo and then looked closer and been like, 'that's me pumping'."</p> <p dir="ltr">Mrs Schmock said she had no idea you could be fined for readjusting your seat belt, and shared the story of the fine on social media. </p> <p dir="ltr">Other mums chimed in on the incident, saying they were grateful for Meagan’s story. </p> <p dir="ltr">"I felt a lot of support from that - realising that a lot more (mums) didn't know," Mrs Schmock said.</p> <p dir="ltr">Another Queensland mum also learned the same lesson the hard way.</p> <p dir="ltr">The same seatbelt camera also captured her in the passenger seat pumping breast milk and she was fined $413 and three demerit points.</p> <p dir="ltr">"As a breastfeeding mum - and I'm sure any other mums who have breastfeed or who have pumped before know that - you can't just really wait," Mrs Schmock said.</p> <p dir="ltr">Meagan and Benjamin Schmock are now disputing the fine with the Department of Transport and Main Roads, and they are considering exploring the potential for a seat belt exemption due to a medical condition.</p> <p dir="ltr"><em>Image credits: A Current Affair</em></p>

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Type 1 diabetes sufferers in for price hike

<p>Those suffering from Type 1 diabetes will be hit with a steep hike in prescription costs when a life-changing insulin is removed from the Pharmaceutical Benefits Scheme (PBS) in April 2023.</p> <p>Local Member for Fairfax Ted O’Brien and Shadow Minister for Health and Aged Care Senator Anne Ruston have revealed 15,000 Australian families will be affected when the drug Fiasp becomes less accessible from April 1.</p> <p>Fiasp is a mealtime insulin that is designed to improve blood sugar control in diabetes sufferers at a faster rate than alternative diabetes medications.</p> <p>Mr O’Brien said he was made aware of the issue by the mother of a young high school student on the Sunshine Coast “whose quality of life will now be at risk from the government’s decision”.</p> <p>“Freya Goldston is a 14-year-old, high-performing student in my electorate who will tell anybody about the remarkable impact that this medicine has had on her life,” Mr O’Brien said.</p> <p>“Freya’s family will have her prescription go from around $7 to more than $280 at a time when households are already under serious financial pressure.</p> <p>“The Labor Government needs to provide an immediate solution to support the 15,000 families who will otherwise need to start making decisions about what household expenses they can cut back on to afford this life-changing medicine.”</p> <p>Mr O’Brien shared the former Coalition Government listed Fiasp on the PBS in 2019 to ensure accessible prices to the fast-acting insulin for diabetes patients.</p> <p>“But now, without any consultation or support for the patients impacted, the government’s decision to suddenly remove Fiasp from the PBS is sending the price soaring,” he said.</p> <p>A spokesperson for Health Minister Mark Butler said his office was alerted of the drug manufacturer Novo Nordisk removing Fiasp from the PBS on February 22 2023.</p> <p>“The minister’s office is now working with the department and Novo Nordisk,” the spokesperson said.</p> <p>“We understand the decision by Novo Nordisk to remove Fiasp from the PBS has been concerning for many Australians living with diabetes and their families.”</p> <p>The spokesperson did not comment on whether there was consultation or support for impacted diabetics when Mr Butler was approached about the removal of Fiasp.</p> <p>Nearly 28,000 people have signed a petition online created by Belinda Moore called “Save Fiasp from falling off the PBS”.</p> <p>“The Australian diabetes community will keep advocating until we witness no evidence of inequitable access to diabetes services, clinicians, technology and therapies.”</p> <p>Ms Ruston also said he was disappointed in the government's decision as Australians are already suffering from a cost-of-living crisis, and the removal of Fiasp from the PBS will affect thousands of Australians.</p> <p>“The government must urgently guarantee that they will provide sufficient support to ensure the viability of affordable diabetes medications in Australia,” Ms Ruston said.</p> <p><em>Image credit: Shutterstock</em></p>

Caring

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Pumping loud music is putting more than 1 billion young people at risk of hearing loss

<p>Music is an integral part of human life. It’s all around us, just like sunshine, lifting our mood. We enjoy it so much that many of us take it with us everywhere on our phones or we spend weekends hitting the club scene, live-music venues or concerts.</p> <p>Meanwhile, many of us may have felt annoyed by loud sound from music venues or remarked on sound emanating from someone else’s headphones. We’re probably aware we should prevent hearing loss from loud industrial noise at work or from using power tools at home. </p> <p>A systematic review released today in <a href="https://globalhealth.bmj.com/lookup/doi/10.1136/bmjgh-2022-010501">BMJ Global Health</a> reports unsafe listening practices in adolescents and young adults from using personal listening devices (such as phones or digital music players) and going to loud clubs and gigs are common, and could be a major factor contributing to hearing loss. </p> <p>In fact, the authors estimate the pumping tunes could be placing up to 1.35 billion young people at risk of hearing loss worldwide.</p> <h2>What the study looked at</h2> <p>Systematic analysis involves looking across multiple studies to identify consistent findings. In this study, the authors included 33 peer-reviewed studies published between 2000 and 2021, involving over 19,000 people, aged 12–34. </p> <p>In the study, unsafe listening was identified as listening at levels above 80 decibels for over 40 hours per week. For context, this is the level above which most Australian states <a href="https://www.safeworkaustralia.gov.au/safety-topic/hazards/noise/overview#:%7E:text=Workers%20must%20not%20be%20exposed,on%20decibels%20and%20time%20exposed.">require industry</a> to implement noise protection processes such as use of hearing protectors.</p> <p>The study confirms the rate of unsafe listening practices is high in adolescents and young adults: 23.81% of them were listening to music on personal devices at unsafe levels and 48.2% at loud entertainment venues (though this rate is less certain). Based on global estimates of population, this translates to up to 1.35 billion young people at risk of hearing loss globally. The World Health Organization <a href="https://www.who.int/health-topics/hearing-loss#tab=tab_1">estimates</a> over 430 million people worldwide already have a disabling hearing loss and prevalence could double if hearing loss prevention is not prioritised.</p> <p>The results tally with our previous studies conducted by Australia’s National Acoustic Laboratories and HEARing Cooperative Research Centre. </p> <p>More than a decade ago we <a href="https://acc.hearingservices.gov.au/wps/wcm/connect/hso/f1f6299d-96f3-408e-be4b-0775af6d7f41/Lifetime_profile_exposure_sound_what_safe_HLPP2.pdf?MOD=AJPERES">reported</a> a high potential for hearing loss from attendance at nightclubs, pubs and live concerts in young Australians aged between 18–35 years. </p> <p>Back then, we found 13% of young Australians (aged 18–35) were getting a yearly noise dose from nightclubs, concerts and sporting activities that exceeded the maximum acceptable dose in industry. In 2015, the WHO launched the <a href="https://www.who.int/activities/making-listening-safe">Make listening Safe</a>initiative to encourage young people to protect their hearing.</p> <h2>Why it’s bad for your hearing</h2> <p>So what’s the problem with loud music? Like sunshine, overexposure can lead to harm. </p> <p>Loud noise, including music, can <a href="https://www.cdc.gov/nceh/hearing_loss/how_does_loud_noise_cause_hearing_loss.html">kill off hair cells and membranes</a> in the inner ear (the cochlea). Once hearing is lost, a person mightn’t be able to hear or understand speech or sounds around them. </p> <p><a href="https://www.nidcd.nih.gov/health/noise-induced-hearing-loss">Research</a> shows hearing loss results from a combination of sound being too loud (and it doesn’t need to be painful to cause hearing damage), listening to loud sound too long (and the louder the sound, the less time you can listen before your hearing is at risk) and how often you are exposed (and hearing damage is cumulative over time). </p> <p>A good “rule of ear” is that if you hear ringing in your ears at or after listening, you are at risk of damaging your hearing. This type of hearing loss is <a href="https://www.cdc.gov/nceh/hearing_loss/how_does_loud_noise_cause_hearing_loss.html">permanent</a> and may require use of hearing aids or cochlear implants.</p> <h2>Wait, so no loud music at all?</h2> <p>So what can we do, short of throwing away our headphones and avoiding clubbing and live music?</p> <p>First, just like with the sun and skin, we need to be aware of the risks to our hearing and take the necessary steps to protect ourselves. We need to be aware of how loud sound is around us and how to keep our exposure within safe levels. We can do this by using personal hearing protection in clubs (such as <a href="https://www.nytimes.com/wirecutter/reviews/best-earplugs-for-concerts/">ear muffs or ear plugs</a> that are fit for purpose), or limiting how often we visit noisy music venues or how long we stay at really loud ones.</p> <p>In Australia, people can access a free <a href="https://knowyournoise.nal.gov.au/">noise risk calculator</a> to calculate their personal risk using an online sound level meter, and to explore how changes in lifestyle could protect their hearing while still allowing them to enjoy music.</p> <p>Most phones now come with software that can <a href="https://www.headphonesty.com/2022/03/iphone-headphone-safety/#:%7E:text=Key%20features%20of%20the%20iPhone%20Headphone%20Safety%20feature&amp;text=According%20to%20the%20WHO%20standard,risk%20of%20sustaining%20hearing%20damage.">monitor safe listening levels</a> and limit exposure.</p> <p>Hearing protection at the venue level is more challenging and may require regulatory and industry-based approaches. Our <a href="https://academic.oup.com/annweh/article/64/4/342/5811673">2020 research</a> identified hazard controls for entertainment venues, such alternating volume between louder and softer levels, rotating staff, providing quiet rooms, and raising speaker locations above head height. We also showed DJs and venues were open to initiatives aimed at reducing the risk of hearing loss for their patrons and <a href="https://www.tandfonline.com/doi/abs/10.1080/19338244.2020.1828241?journalCode=vaeh20">staff</a>. </p> <p>Compromises are possible and they could enable enjoyment of music at live-music venues, while still protecting hearing. That way everyone will be able keep enjoying music for longer.</p> <p><em>Image credits: Getty Images</em></p> <p><em>This article originally appeared on <a href="https://theconversation.com/pumping-loud-music-is-putting-more-than-1-billion-young-people-at-risk-of-hearing-loss-194537" target="_blank" rel="noopener">The Conversation</a>.</em></p>

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Could sound replace pacemakers and insulin pumps?

<p>Imagine a future in which crippling epileptic seizures, faltering hearts and diabetes could all be treated not with scalpels, stitches and syringes, but with sound. Though it may seem the stuff of science fiction, a <a href="https://dx.doi.org/10.1038/s41467-022-28205-y" target="_blank" rel="noreferrer noopener">new study</a> shows that this has solid real-world potential.</p><p><a href="https://sonogenetics.salk.edu/" target="_blank" rel="noreferrer noopener">Sonogenetics</a> – the use of ultrasound to non-invasively manipulate neurons and other cells – is a nascent field of study that remains obscure amongst non-specialists, but if it proves successful it could herald a new era in medicine.</p><p>In the new study published in <em>Nature Communications</em>, researchers from the Salk Institute for Biological Studies in California, US, describe a significant leap forward for the field, documenting their success in engineering mammalian cells to be activated using ultrasound.</p><p>The team say their method, which they used to activate human cells in a dish and brain cells inside living mice, paves the way toward non-invasive versions of deep brain stimulation, pacemakers and insulin pumps.</p><p>“Going wireless is the future for just about everything,” says senior author Dr Sreekanth Chalasani, an associate professor in Salk’s Molecular Neurobiology Laboratory. “We already know that ultrasound is safe, and that it can go through bone, muscle and other tissues, making it the ultimate tool for manipulating cells deep in the body.”</p><p>Chalasani is the mastermind who first established the field of sonogenetics a decade ago.</p><p>He discovered that ultrasound — sound waves beyond the range of human hearing — can be harnessed to control cells. Since sound is a form of mechanical energy, he surmised that if brain cells could be made mechanically sensitive, then they could be modified with ultrasound.</p><p>In 2015 his research group provided the first successful demonstration of the theory, adding a protein to cells of a roundworm, <em>Caenorhabditis elegans</em>, that made them sensitive to low-frequency ultrasound and thus enabled them to be activated at the behest of researchers.</p><p>This was a milestone achievement for the credibility of the field, but Chalasani’s team soon hit a stumbling block. The same protein that was so successful in sensitising roundworm cells produced no discernible effect at all in mammalian cells. While sonically controlling roundworms is undoubtedly cool, without making the leap to mammalian cells, the potential medical revolution would be dead in its tracks.</p><p>Undeterred, Chalasani and his colleagues set out to search for a new protein that would work in mammals.</p><p>Although a few proteins were already known to be ultrasound sensitive, no existing candidates were sensitive at the clinically safe frequency of 7MHz – so this was where the team set their sights.  </p><p>“Our approach was different than previous screens because we set out to look for ultrasound-sensitive channels in a comprehensive way,” says Yusuf Tufail, a former project scientist at Salk and a co-first author of the new paper.</p><p>The screening process took over a year and encompassed nearly 300 candidate proteins which they tested on dishes of a common human research cell line, but at last the team struck gold. TRPA1, a channel protein that lets cells respond to the presence of noxious compounds and activates a wide range of cells in the body, was the winner, responding to the 7MHz ultrasound frequency.</p><p>“We were really surprised,” says co-first author of the paper Marc Duque, a Salk exchange student. “TRPA1 has been well-studied in the literature but hasn’t been described as a classical mechanosensitive protein that you’d expect to respond to ultrasound.”</p><p>To test whether TRPA1 could activate cell types of clinical interest in response to ultrasound, the team used a gene therapy approach to add the genes for human TRPA1 to a specific group of neurons in the brains of living mice. When they then administered ultrasound to the mice, only the neurons with the TRPA1 genes were activated.</p><p>This leap from theory to physical demonstration is a huge step forward for the burgeoning field. Though it is early days, Chalasani believes the next steps are within reach.</p><p>Clinicians treating conditions including Parkinson’s disease and epilepsy currently use deep brain stimulation, which involves surgically implanting electrodes in the brain, to activate certain subsets of neurons. Chalasani says that sonogenetics could one day replace this approach—the next step would be developing a gene therapy delivery method that can cross the blood-brain barrier, something that is already being studied.</p><p>Perhaps sooner, he says, sonogenetics could be used to activate cells in the heart, as a kind of pacemaker that requires no implantation.</p><p>“Gene delivery techniques already exist for getting a new gene – such as TRPA1 – into the human heart. If we can then use an external ultrasound device to activate those cells, that could really revolutionise pacemakers.”</p><p>Though sonogenetics could one day circumvent medications and invasive surgeries, for now the team is sticking with nailing down the fundamentals. Their current focus is on determining exactly how TRPA1 senses ultrasound, which could allow this sensitivity to be tweaked and enhanced.</p><p><img id="cosmos-post-tracker" style="height: 1px!important;width: 1px!important;border: 0!important" src="https://syndication.cosmosmagazine.com/?id=181725&amp;title=Could+sound+replace+pacemakers+and+insulin+pumps%3F" width="1" height="1" data-spai-target="src" data-spai-orig="" data-spai-exclude="nocdn" /></p><div id="contributors"><p><em><a href="https://cosmosmagazine.com/health/sonogenetics-replace-invasive-medical-treatments/" target="_blank" rel="noopener">This article</a> was originally published on <a href="https://cosmosmagazine.com" target="_blank" rel="noopener">Cosmos Magazine</a> and was written by <a href="https://cosmosmagazine.com/contributor/jamie-priest" target="_blank" rel="noopener">Jamie Priest</a>. Jamie Priest is a science journalist at Cosmos. She has a Bachelor of Science in Marine Biology from the University of Adelaide.</em></p><p><em>Image: Getty Images</em></p></div>

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10 ways to get better fuel mileage – and pay less at the pumps

<p><strong>Get better fuel mileage by driving slower</strong></p> <p><span>Hard acceleration in stop-and-go driving costs you 20 per cent in fuel mileage. If you live your life in rush hour traffic and like to put the pedal to the metal, spend all your extra time at the next traffic light figuring out how you could have spent the money you’re wasting.</span></p> <p><strong>Get better fuel mileage by keeping your tyres at the right pressure</strong></p> <p><span>Surveys show that 60 per cent of the vehicles on the road have tyres that are under-inflated by at least 30 per cent. That’s at least 9 psi below the manufacturer’s recommended pressure. That can cost you almost 7 per cent in wasted petrol. Plus, low air pressure causes premature tyre wear, and that can cost almost $300 over the life of the tyres. For best results, check your tyre’s air pressure with a digital pressure gauge (from any auto parts store) and fill to the recommended pressure shown on the decal inside the driver’s door or on the driver’s door pillar.</span></p> <p><strong>Save on fuel by changing spark plugs</strong></p> <p>If your 160,000-km spark plugs have 130,000 km on them, they’re 80 per cent worn. Misfires and incomplete combustion occur more frequently during that last 32,000km, costing you hundreds of dollars in wasted fuel. You have to replace your spark plugs anyway, so do it early and pocket the savings. Even if you have to replace the plugs one extra time over the life of your car, you’ll still come out way ahead. And don’t automatically assume your plugs are good for 160,000km. Many four-cylinder engines require new spark plugs at either 50,000- or 100,000-km intervals.</p> <p><strong>Get better fuel mileage by changing your air filter</strong></p> <p><span>Your engine sucks in 53-million litres of air through the filter every year. On older vehicles (pre-1999), a dirty air filter increases fuel usage by almost 10 per cent. On newer vehicles, the computer is smart enough to detect the lower airflow, and it cuts back on fuel. So your engine will lack power and pick-up. Check the filter when you change your oil and replace it at least once a year, or more if you drive in dirty, dusty conditions.</span></p> <p><strong>Save on fuel by keeping your car aligned</strong></p> <p><span>If your tyres are bowed out of alignment by just 4.2cm, it’s the equivalent of dragging your tyre sideways for 164km for every 32,000 you drive. That’ll cost you hundreds a year in wasted fuel. It will also wear your tyres faster, costing you hundreds more. Here’s an easy way to check your alignment without taking your car in to the shop: Buy a tread depth gauge and measure the tread depth on both edges of each tyre (rear tyres too). If one side of the tyre is worn more than the other, your car needs to be aligned.</span></p> <p><strong>Get better fuel mileage by replacing a broken or missing spoiler</strong></p> <p><span>The plastic air dam (aka “spoiler”) that’s broken or missing wasn’t installed just for a sporty look. If your car had an air dam, driving without it or with a damaged one can reduce your fuel mileage. The air dam literally “dams off” airflow to the undercarriage of your car, forcing the air up and over the hood. That helps your car cut through the air with less drag. It also increases airflow to the A/C condenser and radiator, reducing the load on your car’s electrical system.</span></p> <p><strong>Get better fuel mileage by reducing drag</strong></p> <p><span>Yes, you’ve heard it before, but how about some real world numbers to drive the point home? Aerodynamic drag is a minor concern in city driving, but it really kills your petrol mileage at speeds over 90km/h. In fact, increasing your speed to 105km/h increases drag by 36 per cent! If you do a lot of highway driving, getting to your destination a few minutes early could cost you hundreds of dollars extra a year. Keep it closer to 90km/h and use your cruise control. It will pay off.</span></p> <p><strong>Get better fuel mileage by replacing oxygen sensors before the dashboard warning light goes on</strong></p> <p><span>Oxygen sensors monitor the efficiency of combustion by tracking the amount of oxygen remaining in the exhaust. But they degrade over time and that can cost you up to 15 per cent in fuel mileage. When they fail, the computer lights up your “service engine soon” light, forcing you to incur a diagnostic fee. (Here’s why you should never ignore your car’s check engine light.) On pre-1996 vehicles, replace your oxygen sensor every 96,000km to keep your mileage at its peak. On 1996 and newer vehicles, replace the sensors every 160,000km. Oxygen sensors vary in cost, from around $65 to over $300. Some vehicles have as many as four, but the sensors installed behind the catalytic converter rarely fail.</span></p> <p><strong>Replace your cabin air filter</strong></p> <p>A clogged cabin air filter can damage your car’s blower motor and cause your AC to run longer and harder in the summer. Cabin air filters are easy to access and replace and you’ll save money by doing it yourself. Buy a replacement cabin air filter at any auto parts store and ask the retailer to print out the installation instructions. Cabin air filters are usually located in the air ducts behind the glove box in late model vehicles. However, some car makers locate them in the cowling or console area. Just remove the access covers and slide out the old filter. Note the direction of the airflow arrows so you can install the new filter in the proper orientation. Then reinstall the covers and you’re done.</p> <p><strong>Keep an eye on warning lights</strong></p> <p><span>Pay attention to your dashboard warning lights. Car owners think a glowing check engine light isn’t important because it just means you’ve got an “emissions problem.” Guess what? Emissions problems are almost always caused by an incomplete burn and that means you’re not getting the most bang for your buck. In other words, a check light means you’re wasting fuel. Worse yet, all that extra fuel goes right into your expensive catalytic converter, causing it to fail early. A new catalytic converter can be expensive to replace and then you STILL have to fix the underlying problem that turned on the check engine light in the first place. Many times the check engine light comes on due to a bum sensor or vacuum leak. Replacing a sensor or fixing a vacuum leak can save far more than what you’ll waste in reduced fuel economy.</span></p> <p><em><span>This article first appeared in </span><a rel="noopener" href="https://www.readersdigest.com.au/food-home-garden/money/12-ways-to-get-better-fuel-mileage-and-pay-less-at-the-pumps" target="_blank"><span>Reader’s Digest</span></a><span>. For more of what you love from the world’s best-loved magazine, </span><a rel="noopener" href="http://readersdigest.innovations.com.au/c/readersdigestemailsubscribe?utm_source=over60&amp;utm_medium=articles&amp;utm_campaign=RDSUB&amp;keycode=WRA87V" target="_blank"><span>here’s our best subscription offer.</span></a></em></p> <p><em>Image: Getty Images</em></p> <p><img style="width: 100px !important; height: 100px !important;" src="https://oversixtydev.blob.core.windows.net/media/7820640/1.png" alt="" data-udi="umb://media/f30947086c8e47b89cb076eb5bb9b3e2" /></p>

Money & Banking

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New ‘smart’ insulin could revolutionise Type 1 diabetes treatment

<p><span style="font-weight: 400;">For the 15 in every 100,000 people with Type 1 diabetes, living with the condition often involves balancing diet, exercise, and insulin therapy to keep blood sugar levels in a normal range.</span></p> <p><span style="font-weight: 400;">Though there are a plethora of solutions being developed to help those with diabetes live more easily, a new approach has focused on insulin itself.</span></p> <p><span style="font-weight: 400;">Dr Michael Weiss, a biochemist from the School of Medicine at Indiana University, has worked with colleagues to tweak the structure of insulin so it responds to the presence of a simple sugar molecule.</span></p> <p><img style="width: 500px; height:231px;" src="https://oversixtydev.blob.core.windows.net/media/7843122/image-for-release_weiss_pnas.jpg" alt="" data-udi="umb://media/411d3753b46448bb978e1922daac8560" /></p> <p><em><span style="font-weight: 400;">Image: IU School of Medicine</span></em></p> <p><span style="font-weight: 400;">The researchers have utilised a feature already built into insulin’s structure - a “hinge” that enables the molecule to function when open and keeps it stable while closed.</span></p> <p><strong>What the study found</strong></p> <p><span style="font-weight: 400;">The experiments performed by Dr Weiss and his team used the carbohydrate fructose to manipulate insulin, so that it would only be ‘switched on’ by the presence of a certain amount of sugar, causing it to activate a sample of cells derived from the liver.</span></p> <p><span style="font-weight: 400;">Though the experiments were more confirmation that the concept would be viable than an actual treatment, it would theoretically work for an insulin shaped to activate in the presence of glucose.</span></p> <p><strong>Why it matters</strong></p> <p><span style="font-weight: 400;">Weiss envisions a future where people don’t have to worry about their blood sugar falling too low (hypoglycemia) or too high (hyperglycemia), which can result in symptoms such as delirium, convulsions, blindness, or strokes.</span></p> <p><span style="font-weight: 400;">“The promise of this kind of ‘smart’ insulin is that it would transform diabetes care, so people wouldn’t have to worry anymore,” Weiss </span><a rel="noopener" href="https://medicine.iu.edu/news/2021/07/Synthetic-hinge-could-hold-key-to-revolutionary-smart-insulin-therapy" target="_blank"><span style="font-weight: 400;">said</span></a><span style="font-weight: 400;">.</span></p> <p><span style="font-weight: 400;">“With our invention, we envision that when the blood sugar goes too low, the hinge would close,” he explained.</span></p> <p><span style="font-weight: 400;">Though a lot needs to happen before this invention is incorporated into treatments, it could help affected individuals be able to manage their sugar levels and improve their quality of life.</span></p> <p><span style="font-weight: 400;">This research was published in </span><em><a rel="noopener" href="https://www.pnas.org/content/118/30/e2103518118" target="_blank"><span style="font-weight: 400;">PNAS</span></a></em><span style="font-weight: 400;">.</span></p> <p><em><span style="font-weight: 400;">Image: IU School of Medicine, Getty</span></em></p>

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Harrowing near miss for bystander at petrol pump

<div class="post_body_wrapper"> <div class="post_body"> <div class="body_text "> <p>Shocking CCTV footage posted online shows a near-miss by a Tasmanian driver at a petrol station.</p> <p>A woman narrowly avoided serious injury as the driver in front drove off from the petrol pump with the fuel nozzle still attached to their vehicle.</p> <p>A black car is seen driving away from the pump, which causes the hose connecting the petrol bowser and the vehicle to stretch.</p> <p>The pressure quickly becomes too much and the hose snaps back from the vehicle, almost hitting a woman in the head.</p> <iframe src="https://www.facebook.com/plugins/video.php?href=https%3A%2F%2Fwww.facebook.com%2FTaspetroleum1%2Fvideos%2F1151317785225218%2F&amp;show_text=true&amp;width=734&amp;height=757&amp;appId" width="734" height="757" style="border: none; overflow: hidden;" scrolling="no" frameborder="0" allowtransparency="true" allow="encrypted-media" allowfullscreen="true"></iframe> <p>The woman and another driver can be seen watching on in confusion, with Tasmania Petroleum hoping to track down who caused the incident.</p> <p>"Can anyone put us in touch with the driver of a Black Mitsubishi Challenger, Rego FH 0659?" the company wrote on Facebook.</p> <p>"And also the innocent bystander, driving a green Toyota hatch Rego FR1852, who was very lucky to walk away! We are sorry for your unfortunate bad experience on our site, and would like to give you some free fuel."</p> </div> </div> </div>

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From coronavirus tests to open-source insulin and beyond, ‘biohackers’ are showing the power of DIY science

<p>In March, amateur scientists in Sydney announced they had created a <a href="https://www.abc.net.au/news/2020-03-25/amateur-scientist-making-a-rapid-test-for-coronavirus/12084974">COVID-19 test kit</a> that is simpler, faster, and cheaper than existing tests. While the test has not yet been approved by regulators, if effective it could play a role in scaling up the world’s coronavirus testing capability.</p> <p>The test’s creators, associated with a “community lab for citizen scientists” called <a href="https://foundry.bio/">Biofoundry</a>, are part of a growing international movement of “biohackers” with roots stretching back <a href="https://www.newscientist.com/article/mg12516984-100-forum-roses-are-black-violets-are-green-the-emergence-of-amateur-genetic-engineers/">30 years or more</a>. Biohacking, also known as DIY biology, takes cues from computer-hacking culture and uses the tools of biological science and biotechnology to carry out experiments and make tools outside any formal research institution.</p> <p><strong>Who’s afraid of biohacking?</strong></p> <p>But biohacking is under threat as governments, wary of potential risks, pass laws to restrict it. A more balanced approach is needed, for the benefit of science and society.</p> <p>As biohacking has gained increased visibility, it has also attracted increased scrutiny. Media coverage has played up the risks of biohacking, whether <a href="https://www.bbc.com/future/article/20130124-biohacking-fear-and-the-fbi">from malice</a> (“bioterror”) or <a href="https://www.bloomberg.com/news/articles/2018-06-29/autopsy-reveals-biohacker-traywick-died-from-accidental-drowning">by accident</a> (“bioerror”).</p> <p>Local and national governments have also sought to legislate against the practice.</p> <p>In August 2019, politicians in California <a href="https://www.vox.com/future-perfect/2019/8/13/20802059/california-crispr-biohacking-illegal-josiah-zayner">introduced a law</a> that forbids the use of CRISPR gene-editing kits outside professional labs. Australia has some of the world’s most stringent regulations, with the <a href="http://www.ogtr.gov.au/internet/ogtr/publishing.nsf/Content/9AA09BB4515EBAA2CA257D6B00155C53/%24File/06%20-%20Biohacking%20and%20community%20science.pdf">Office of the Gene Technology Regulator</a> monitoring the use of genetically modified organisms and risks to public health and safety.</p> <p>Some authorities have gone so far as to arrest biohackers on <a href="https://www.nytimes.com/2008/04/22/nyregion/22bioart.html">suspicion of bioterrorism</a>.</p> <p>But such anxieties around biohacking are largely unfounded.</p> <p><a href="https://www.youtube.com/watch?v=AWEpeW7Ojzs">Ellen Jorgensen</a>, co-founder of the <a href="https://www.genspace.org/">Genspace</a> community lab in New York, argues that such responses overestimate the abilities biohackers and underestimate their ethical standards. <a href="https://www.wilsoncenter.org/publication/seven-myths-and-realities-about-do-it-yourself-biology-0">Research shows</a> shows the great majority of biohackers (92%) work within community laboratories, many of which operate under the <a href="https://diybio.org/codes/">Ethical Code for Safe Amateur Bioscience</a> drawn up by the community in 2011.</p> <p><strong>Connoisseurs of science</strong></p> <p>One way to think of biohackers is as what the Belgian philosopher Isabelle Stengers calls <a href="https://books.google.com.au/books/about/Another_Science_is_Possible.html?id=e1hHDwAAQBAJ&amp;printsec=frontcover&amp;source=kp_read_button&amp;redir_esc=y#v=onepage&amp;q&amp;f=false">“connoisseurs of science”</a>.</p> <p>Somewhere between an expert and an amateur, a connoisseur is able to relate to scientific knowledge and practice in an informed way, but can also pose new questions that scientists are unable to.</p> <p>Connoisseurs can hold scientists to account and challenge them when they skip over concerns. They highlight how science might be done better. Like other pursuits such as music or sport, science can benefit from a strong and vibrant culture of connoisseurs.</p> <p>Biohackers are an important node in the relationship between science institutions and wider society. Stengers highlights how it is not enough for there to be a relationship between science and society. It is the nature and quality of this relationship that matters.</p> <p><strong>A two-way relationship</strong></p> <p>Traditional models of science communication assume a one-way relationship between science and society at large, with scientists transmitting knowledge to a public who passively receive it. Biohackers instead engage people as active participants in the production and transformation of scientific knowledge.</p> <p>Biohacking labs like BioFoundry and Genspace encourage hands-on engagement with biotechnologies through classes and open workshops, as well as projects on local environmental pollution.</p> <p>Biohackers are also making discoveries that advance our understanding of current scientific problems. From devising coronavirus tests to making science equipment out of <a href="https://hackteria.org/wiki/DIY_microscopy">everyday items</a> and producing <a href="https://openinsulin.org/">open-source insulin</a>, biohackers are reshaping the sense of where scientific innovation happens.</p> <p><strong>From law to ethics</strong></p> <p>While biohacking can produce great benefits, the risks can’t be neglected. The question is how best to address them.</p> <p>While laws and regulations are necessary to prevent malicious or dangerous practice, their overuse can also push biohackers underground to tinker in the shadows. Bringing biohackers into the fold of existing institutions is another approach, although this could threaten the ability of biohackers to pose tough questions.</p> <p>In addition to law, ethical guidelines and codes drawn up by the biohacking community themselves offer a productive way forward.</p> <p>For Stengers, an “ethical” relationship is not based on the domination or capture of one group by another. It instead involves symbiotic modes of engagement in which practices flourish together and transform each other.</p> <p>A balance between law and ethics is necessary. The <a href="https://diybio.org/codes/">2011 code of ethics</a> drawn up by biohackers in North America and Europe is a first step toward what a more open, transparent, and respectful culture of collaboration could look like.</p> <p>In the US we have seen experiments with a more <a href="https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5278613/">open and symbiotic relationship</a> between the FBI and the biohacking community in recent years.</p> <p>But this is just the beginning of a conversation that is in danger of stalling. There is much to lose if it does.</p> <p><em>Written by Andrew Lapworth. Republished with permission of </em><a href="https://theconversation.com/from-coronavirus-tests-to-open-source-insulin-and-beyond-biohackers-are-showing-the-power-of-diy-science-138019"><em>The Conversation.</em></a></p>

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