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Category: engineering

Israeli professor leads int’l team behind implantable device that could eliminate need for insulin shots

Assistant Professor Shady Farah from the Technion – Israel Institute of Technology’s Faculty of Chemical Engineering – has led an international research team that pioneered the development of an implantable, self-regulating device that produces insulin for patients with diabetes. The research is considered groundbreaking and could potentially eliminate the need for daily insulin shots.

The multinational study was conducted in cooperation with scientists from leading U.S. institutions, including the Massachusetts Institute of Technology (MIT), Harvard University, Johns Hopkins University and the University of Massachusetts.

The study, published last month in Science Translational Medicine, describes the implant as a self-regulating ‘artificial pancreas’ that monitors blood glucose levels and produces insulin internally, eliminating the need for external insulin shots. The researchers describe the technology as a ‘crystalline shield’ and report that it can operate in the body for years.

Technion researchers developed an implantable artificial pancreas that produces insulin, potentially eliminating daily shots for diabetes patients.

Helion hits new fusion milestone: D-T fusion and 150M°C plasma temperatures

Helion has achieved a significant milestone in fusion energy by successfully demonstrating deuterium-tritium fusion with plasma temperatures reaching 150 million degrees Celsius.

## Questions to inspire discussion.

Fusion Performance Achievements.

🔥 Q: What fusion performance records did Helion’s Polaris achieve?

A: Polaris became the first privately funded fusion machine to demonstrate measurable deuterium-tritium (DT) fusion while reaching plasma temperatures exceeding 150 million degrees Celsius, proving the ability to compress and hold fusion plasma for more pressure, more heat, and more fusion.

Operational Execution.

Continue reading “Helion hits new fusion milestone: D-T fusion and 150M°C plasma temperatures” | >

Committee co-chaired by Prof. Dava Newman issues a new roadmap for human missions to Mars

On December 9, the National Academies of Sciences, Engineering, and Medicine (NASEM) released a landmark report, A Science Strategy for the Human Exploration of Mars, laying out a comprehensive case for future crewed Mars missions. The report, authored by the Committee on a Science Strategy for the Human Exploration of Mars that was co-chaired by Prof. Dava Newman, defines the highest-priority scientific objectives for humans on the Martian surface.

At the top of the list: searching for evidence of past or present life. “We’re searching for life on Mars,” said Newman in an interview with Ars Technica. “The answer to the question ‘are we alone?’ is always going to be ‘maybe,’ unless it becomes yes.”

The report identifies 11 top science goals for initial human missions, including biosignature/habitability experiments and water and CO₂ cycle studies, geology mapping, radiation monitoring, dust-storm research, and assessments of how Martian conditions affect humans and ecosystems.

New sound-based 3D-printing method enables finer, faster microdevices

Concordia researchers have developed a new 3D-printing technique that uses sound waves to directly print tiny structures onto soft polymers like silicone with far greater precision than before. The approach, called proximal sound printing, opens new possibilities for manufacturing microscale devices used in health care, environmental monitoring and advanced sensors. It is described in the journal Microsystems & Nanoengineering.

The technique relies on focused ultrasound to trigger chemical reactions that solidify liquid polymers exactly where printing is needed. Unlike conventional methods that rely on heat or light, sound-based 3D-printing works with key materials used in microfluidic devices, lab-on-a-chip systems and soft electronics that are hard to print at small scales.

This work builds on the research team’s earlier breakthrough in direct sound printing, which first showed that ultrasound could be used to cure polymers on demand. While that earlier method demonstrated the concept, it struggled with limited resolution and consistency. The new proximal approach places the sound source much closer to the printing surface, allowing far tighter control.

New study explains chemotherapy resistance in lung and ovarian cancers

Researchers have identified a biological mechanism that helps explain why some lung and ovarian cancers become resistant to chemotherapy, offering insight into why cancers recur. The study, published in Nature Aging this month, investigated how platinum-based chemotherapies such as cisplatin negatively affect tumor behavior in non-small cell lung cancer (NSCLC) and high-grade serous ovarian cancer (HGSOC). Although these treatments are widely used, their long-term effectiveness is often limited when tumors return or stop responding.

Professor Ljiljana Fruk and Muhamad Hartono from the Department of Chemical Engineering and Biotechnology (CEB) contributed to the international collaboration, led by researchers from the Early Cancer Institute and the Cancer Research UK Cambridge Institute. Their involvement follows her Bionano Engineering group’s recent development of a urine test for early lung cancer detection.

Hologram processing method boosts 3D image depth of focus fivefold

Researchers from the University of Tartu Institute of Physics have developed a novel method for enhancing the quality of three-dimensional images by increasing the depth of focus in holograms fivefold after recording, using computational imaging techniques. The technology enables improved performance of 3D holographic microscopy under challenging imaging conditions and facilitates the study of complex biological structures.

The research results were published in the Journal of Physics: Photonics in the article “Axial resolution post-processing engineering in Fresnel incoherent correlation holography.”

One of the main limitations of conventional microscopes and 3D imaging systems is that, once an image or hologram has been recorded, its imaging properties cannot be altered. To overcome this limitation, Shivasubramanian Gopinath, a Junior Research Fellow at the University of Tartu Institute of Physics, and his colleagues have developed a new method that enables to capture a set of holograms with different focal distances at the time of acquisition, instead of a single image. These can then be computationally combined to produce a synthetic hologram that offers a much greater depth of focus than conventional approaches, and allows for post-processing of the recorded image.

A microfluidic chip monitors gases using integrated, motionless pumps

A new microscale gas chromatography system integrates all fluidic components into a single chip for the first time. The design leverages three Knudsen pumps that move gas molecules using heat differentials to eliminate the need for valves, according to a new University of Michigan Engineering study published in Microsystems & Nanoengineering. The monolithic gas sampling and analysis system, or monoGSA system for short, could offer reliable, low-cost monitoring for industrial chemical or pharmaceutical synthesis, natural gas pipelines, or even at-home air quality.

Gas chromatography has long been considered the gold standard for measuring and quantifying volatile organic compounds—gases emitted from industrial processes, fuels, household products and more. Recently, micro gas chromatography miniaturized the technology to briefcase-size or smaller, bringing gas analysis from the laboratory to the source.

Most micro gas chromatography systems use pumps and valves to move gas molecules from an input port to a preconcentrator, which extracts and concentrates samples, then from the preconcentrator to a column for chemical separation, and then to the detector and finally to an exhaust port. Up to this point, pumps and valves have been fabricated and assembled separately, which increases device size, assembly cost and risk of failure at connection points.

Rolling out the carpet for spin qubits with new chip architecture

Researchers at QuTech in Delft, The Netherlands, have developed a new chip architecture that could make it easier to test and scale up quantum processors based on semiconductor spin qubits. The platform, called QARPET (Qubit-Array Research Platform for Engineering and Testing) and reported in Nature Electronics, allows hundreds of qubits to be characterized within the same test-chip under the same operating conditions used in quantum computing experiments.

“With such a complex, tightly packed quantum chip, things really start to resemble the traditional semiconductor industry,” states researcher Giordano Scappucci.

When viewed under a microscope, the structure of the QARPET chip appears almost woven. Fabrication was in fact a stress test for engineering capabilities.

Electronic friction can be tuned and switched off

Researchers in China have isolated the effects of electronic friction, showing for the first time how the subtle drag force it imparts at sliding interfaces can be controlled. They demonstrate that it can be tuned by applying a voltage, or switched off entirely simply by applying mechanical pressure. The results, published in Physical Review X, could inform new designs that allow engineers to fine-tune the drag forces materials experience as they slide over each other.

In engineering, friction causes materials to wear and degrade over time, and also causes useful energy to be wasted as heat. While this problem can be mitigated through lubricants and smoother surfaces, friction can also arise from deeper, more subtle effects.

Among these is an effect which can occur at metallic or chemically active surfaces as they slide past one another. In these cases, atomic nuclei in one surface can transfer some of their energy to electrons in the other surface, exciting them to higher energy levels. This lost energy produces a drag force that increases with sliding velocity: an effect known as “electronic friction.”

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