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3D cancer microscope ‘could be as revolutionary as ultrasound’

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A 3D microscope that can produce detailed images of tumours could usher in the end of painful biopsies for some types of cancer.

The microscope may also help surgeons be more precise when deciding which bits of tissue to remove so there would be less need to conduct subsequent operations.

The device has been shown to precisely detect pancreatic cancer in living mice and kidney disease in human laboratory samples.

A large-scale clinical trial on humans is slated for later this year.

Professor Elizabeth Hillman, of Columbia University in New York, said:

“This is very exciting. We believe that this technology could be as revolutionary as ultrasound.

“The way that biopsy samples are processed hasn’t changed in 100 years. They are cut out, fixed, embedded, sliced, stained with dyes, positioned on a glass slide, and viewed by a pathologist using a simple microscope.

“This is why it can take days to hear news back about your diagnosis after a biopsy..

“Our 3D microscope overcomes many of the limitations of prior approaches to enable visualization of cellular structures in tissues in the living body.

“It could give a doctor real-time feedback about what type of tissue they are looking at without the long wait.”

The researchers are working to commercialise the Mediscape device and gain approval from the FDA.

They will initially apply to use it for tumour screening and guidance during operations but hope to eventually be allowed to use it for diagnosis.

Chris Bakal, professor of cancer morphodynamics at The Institute of Cancer Research in London, who was not involved in the research, said:

“This is an extraordinary advance – the technology could help clinicians with cancer diagnoses, speeding up tissue analyses.”

“It could be used when performing a biopsy – by extracting tissue from the body and using the Mediscape to examine it in detail.

“Or even, with some modification, it could be used as an endoscope to examine living tissue inside the body.”

Dr Charles Evans, research information manager at Cancer Research UK, added:

“This new technique has the potential to be a big step forward for people with cancer.

“Using surgical biopsies to confirm a cancer diagnosis can be time-consuming and distressing for patients.

“And ensuring all the cancerous tissue is removed during surgery can be very challenging unaided. Any device that can give clinicians the edge over cancer is extremely welcome.

“However, more work will be needed to apply this technique in a device that’s practical for clinicians and to demonstrate whether it can bring benefits for people with cancer, but we look forward to seeing the next steps.”

Image: Kripa Patel-Hillman Lab/Columbia Engineering

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Evening exercise benefits elderly hypertensives

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Evening exercise benefits elderly hypertensives

A study conducted at the University of São Paulo with 23 volunteers found that aerobic exercise performed in the evening benefits elderly hypertensives more than morning exercise.

Aerobic training is known to regulate blood pressure more effectively when practiced in the evening than in the morning.

Researchers who conducted a study of elderly patients at the University of São Paulo’s School of Physical Education and Sports (EEFE-USP) in Brazil concluded that evening exercise is better for blood pressure regulation thanks to improved cardiovascular control by the autonomic nervous system via a mechanism known as baroreflex sensitivity.

Leandro Campos de Brito, first author of the article, commented: “There are multiple mechanisms to regulate blood pressure, and although morning training was beneficial, only evening training improved short-term control of blood pressure by enhancing baroreflex sensitivity.

“This is important because baroreflex control has a positive effect on blood pressure regulation, and there aren’t any medications to modulate the mechanism.”

In the study, 23 elderly patients diagnosed and treated for hypertension were randomly allocated into two groups: morning training and evening training. Both groups trained for ten weeks on a stationary bicycle at moderate intensity, with three 45-minute sessions per week.

Key cardiovascular parameters were analysed, such as systolic and diastolic blood pressure, and heart rate after ten minutes’ rest. The data was collected before and at least three days after the volunteers completed the ten weeks of training.

The researchers also monitored mechanisms pertaining to the autonomic nervous system, which controls breathing, heart rate, blood pressure, digestion, and other involuntary bodily functions, such as muscle sympathetic nerve activity, which regulates peripheral blood flow via contraction and relaxation of blood vessels in muscle tissue, and sympathetic baroreflex sensitivity, assessing control of blood pressure via alterations to muscle sympathetic nerve activity.

In the evening training group, all four parameters analysed were found to improve: systolic and diastolic blood pressure, sympathetic baroreflex sensitivity, and muscle sympathetic nerve activity. In the morning training group, no improvements were detected in muscle sympathetic nerve activity, systolic blood pressure or sympathetic baroreflex sensitivity.

“Evening training was more effective in terms of improving cardiovascular autonomic regulation and lowering blood pressure. This can be partly explained as due to an improvement in baroreflex sensitivity and a reduction of muscle sympathetic nerve activity, which increased in the evening. For now, all we know is that baroreflex control is the decisive factor, from the cardiovascular standpoint at least, to make evening training more beneficial than morning training, since it induces the other benefits analysed. However, much remains to be done in this regard in order to obtain a better understanding of the mechanisms involved,” said Brito, who is currently a professor at Oregon Health & Science University’s Oregon Institute of Occupational Health Sciences in the United States, and continues to investigate the topic via circadian rhythm studies.

Baroreflex sensitivity regulates each heartbeat interval and controls autonomic activity throughout the organism.

“It’s a mechanism that involves sensitive fibres and deformations in the walls of arteries in specific places, such as the aortic arch and carotid body. When blood pressure falls, this region warns the brain region that controls the autonomic nervous system, which in turn signals the heart to beat faster and tells the arteries to contract more strongly. If blood pressure rises, it warns the heart to beat more slowly and tells the arteries to contract less. In other words, it modulates arterial pressure beat by beat,” Brito explained.

In previous studies, the EEFE-USP research group showed that evening aerobic training reduced blood pressure more effectively than morning training in hypertensive men (read more at: agencia.fapesp.br/34194), and that the more effective response to evening training in terms of blood pressure control was accompanied by a greater reduction in systemic vascular resistance and systolic pressure variability (read more at: agencia.fapesp.br/37432).

“Replication of the results obtained in previous studies and in different groups of hypertensive patients, associated with the use of more precise techniques to evaluate the main outcomes, has strengthened our conclusion that aerobic exercise performed in the evening is more beneficial to the autonomic nervous system in patients with hypertension. This can be especially important for those with resistance to treatment with medication,” Brito said.

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Revolutionising cancer treatment: intracellular protein delivery using hybrid nanotubes

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Revolutionising cancer treatment: intracellular protein delivery using hybrid nanotubes

A new hybrid nanotube stamp system has been developed which revolutionises precision medicine with high efficiency and cell viability rates for cancer treatment.

Precision medicine and targeted therapies are gaining traction for their ability to tailor treatments to individual patients while minimising adverse effects. Conventional methods, such as gene transfer techniques, show promise in delivering therapeutic genes directly to cells to address various diseases.

However, these methods face significant drawbacks, hindering their efficacy and safety. Intracellular protein delivery offers a promising approach for developing safer, more targeted, and effective therapies. By directly transferring proteins into target cells, this method circumvents issues such as silencing during transcription and translation and the risk of undesirable mutations from DNA insertion. Additionally, intracellular protein delivery allows for precise distribution of therapeutic proteins within target cells without causing toxicity.

A group of researchers led by Professor Takeo Miyake at Waseda University, Japan in collaboration with the Mikawa Group at the RIKEN Institute have now developed a hybrid nanotube stamp system for intracellular delivery of proteins. This innovative technique enables the simultaneous delivery of diverse cargoes, including calcein dye, lactate oxidase (LOx) enzyme, and ubiquitin (UQ) protein, directly into adhesive cells for cancer treatment.

The researchers explored the therapeutic potential of delivering LOx enzyme for cancer treatment. “Through our innovative stamp system, we successfully delivered LOx into both healthy mesenchymal stem cells (MSC) and cancerous HeLa cells. While MSC cells remained unaffected, we observed significant cell death in HeLa cancer cells following LOx treatment with viabilities decreasing over time. Our findings highlight the promising efficacy of intracellularly delivered LOx in selectively targeting and killing cancer cells, while sparing healthy cells, offering a targeted therapeutic strategy for cancer treatment,” explains Miyake.

Finally, the team successfully delivered 15N isotope-labeled UQ proteins into HeLa cells using the HyNT stamp system. This delivery allowed for the analysis of complex protein structures and interactions within the cells. In addition, optical and fluorescence imaging confirmed the presence of delivered UQ in HeLa cells, and nuclear magnetic resonance spectroscopy matched the intracellular UQ protein concentration with that of a solution containing 15N-labeled UQ. These results demonstrate the effectiveness of the stamp system in delivering target proteins for subsequent analysis.

The results demonstrate the remarkable capability of the HyNT stamp system in delivering LOx and UQ into a substantial number of adhesive cells, as required for regenerative medicine applications. The system achieved a notably high delivery efficiency of 89.9%, indicating its effectiveness in transporting therapeutic proteins into the target cells with precision. Moreover, the cell viability rate of 97.1% highlights the system’s ability to maintain the health and integrity of the treated cells throughout the delivery process.

The HyNT stamp system offers transformative potential in intracellular protein delivery, with applications spanning from cancer treatment to molecular analysis. Beyond medicine, its versatility extends to agriculture and food industries, promising advancements in crop production and food product development. With precise cell manipulation and efficient delivery, the HyNT stamp system is poised to revolutionize biomedical research, clinical practice, and diverse industries, paving the way for personalized interventions and shaping the future of modern medicine.

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Heat waves damage humans’ vital organs, shows new study

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Researchers from the University of California, Irvine have found evidence of the molecular causes of the damaging impact heat stress causes on the gut, liver and brain in the elderly.

The researchers suggest these findings point to the potential of developing precise prognostic and therapeutic interventions.

These organs have a complex and multidirectional communication system that touches everything from our gastrointestinal tract to the nervous system. Whether it is our brain affecting hunger or the liver influencing mental health, understanding the gut-liver-brain communication or “axis” is crucial to protecting human health.

Their study, which was conducted on mouse models, is published in the journal Scientific Reports, a Nature Portfolio journal. It is one of the first to fill the knowledge gap on the effects of heat stress on a molecular level of this crucial biological conversation.

“Inflammation in the brain and spine contributes to cognitive decline, compromises the ability to form new neurons and exacerbates age-related diseases,” said corresponding author, Saurabh Chatterjee, a professor of environmental & occupational health at the UC Irvine Program in Public Health. “By investigating the effects of heat stress on the gut-liver-brain crosstalk, we can better protect our increasingly vulnerable aging population.”

Using RNA analysis and bioinformatics to analyse elderly, heat-stressed mice, Chatterjee and his team found evidence of heat stress-affected genes in the brain and liver. A significant increase in the production of ORM2, a liver-produced protein, was observed in the heat-stressed mice. The control group of unstressed mice did not show a change, providing proof of organ dysfunction in the heat-stressed mice.

Researchers believe that increased secretion of ORM2 is a coping mechanism that may be due to gut inflammation and imbalance. In addition, ORM2 may impact the brain through a leaky blood-brain barrier, emphasizing intricate multi-organ crosstalk.

Additionally, the study shows the potential to use ORM2 for targeted biomarker interventions to prevent liver disease in heat exposure. This observation advances molecular insights into the pathophysiology of adverse heat events and will serve as a foundation for future research.

“Our findings have the potential to be used for the development of prognostic and therapeutic markers for precise interventions,” said Chatterjee. “In a dynamically changing global landscape, the imminent threat of climate change is evident in rising temperatures, raising concerns about intermittent heat waves. Our heating planet is undoubtedly leading to acute and chronic heat stress that harms the health of our aging population.”

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