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New robotic heart mimics common, mysterious condition to help researchers study it
Scientists have invented a soft robotic heart that could give them a new way to study a mysterious condition that accounts for roughly half of all heart failure cases. This form of heart failure, called heart failure with preserved ejection fraction (HFpEF), is a condition in which the heart pumps out a normal amount of blood but becomes too stiff to relax and refill properly between beats. Over 3 million Americans have the condition, but researchers still don't fully understand why it develops, making it difficult to design treatments that directly target the disease. The new device, described June 1 in the journal Nature Communications, is the first soft robotic heart model that can actively adjust how it responds to changes in pressure. It tightens or relaxes its artificial muscles, enabling researchers to control how stiff the heart becomes. This allows it to better mimic a diseased human heart.Current laboratory models of HFpEF have drawbacks. Traditional "mock circulation loops" use rigid pumps and tubing to recreate blood flow but don't physically resemble a beating heart. Lab animals capture more realistic biology but are expensive and don't perfectly mirror human disease, said study co-author Thanh Nho Do, a biomedical engineer and associate professor at the University of New South Wales in Australia."HFpEF has been notoriously difficult to study and treat," Nho Do told Live Science in an email. Earlier versions of the robotic heart could realistically recreate cardiac movement, but they followed present commands that didn't adapt to changing conditions. The new system attempts to solve that limitation by allowing the artificial muscle fibers to "feel" the pressure created by the fluid they are pumping and dynamically contract or relax against it. That feedback is critical for reproducing HFpEF, in which abnormal stiffness rather than weakened pumping lies at the core of the disease.The researchers built a silicone replica of the left side of the human heart and wrapped it in artificial muscle fibers made from rubber tubes reinforced with spring coils. The model continuously senses the pressure generated by the fluid flowing through it and adjusts the force of its artificial muscles in response. By changing how much the muscles resist being stretched as the heart fills, researchers can dial in different levels of stiffness.Instead of modeling a single snapshot of HFpEF, the researchers recreated several stages of the disease's progression. In early stages, patients' hearts start to show impaired relaxation between beats, while in more advanced forms, the heat is so stiff that it can't adequately fill with blood before the next contraction."If we can model its progression pathway, we might be able to use models like ours to develop medical devices that interrupt that trajectory, rather than just treating end-stage disease," Nho Do said. RELATED STORIESThese patients' hearts stopped a dozen times a day. An innovative procedure has transformed their lives.Men develop cardiovascular disease 7 years before women, study suggests. But why?Scientists developing new 'heart-on-a-chip'Current treatment for HFpEF focuses largely on managing symptoms and associated conditions, such as high blood pressure, obesity and diabetes. In recent years, drugs known as SGLT2 inhibitors have been shown to reduce the risk of hospitalization in many patients by reducing excess fluid in the body. But there are still few therapies that directly target the stiffening of the heart muscle.The researchers hope their new model might pave the way, but they emphasized that the work is an early proof of concept. Looking ahead, they hope to develop increasingly sophisticated robot heart models that can complement other data on HFpEF, including that from computer simulations, animal studies and clinical testing. "We hope the biggest impact will be in understanding HFpEF mechanisms and improving the way we develop cardiovascular devices," Nho Do said. Heart quiz: What do you know about the body's hardest-working muscle?
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