Tag:

Cortex

Chemotherapy treatment linked to lasting cognitive changes in rats

by Dr. Michael Lee – Health Editor August 1, 2025

written by Dr. Michael Lee – Health Editor

Chemo Brain Explained: Rat Study Reveals Molecular Clues

New research pinpoints gene activity changes in brain regions crucial for cognition

Scientists have uncovered a potential molecular basis for “chemo brain,” the persistent cognitive impairment experienced by some cancer survivors. A groundbreaking study on rats suggests chemotherapy directly alters gene regulation in key brain areas, offering hope for future targeted therapies.

Gene Disruption Linked to Cognitive Decline

Researchers at The City College of New York (CCNY) have identified how specific chemotherapy drugs impact the brain at a fundamental level. Their findings indicate that the treatment regimen of doxorubicin and cyclophosphamide, commonly used in cancer treatment, significantly boosts the activity of the DNMT3a gene.

This gene plays a critical role in DNA methylation, a process that controls gene expression. The study observed a direct link between elevated DNMT3a and altered DNA methylation patterns within the prefrontal cortex of the rat brain. This region is vital for executive functions such as decision-making and cognitive control.

“Our study explored how chemotherapy affects the brain at the molecular level using an animal model. We found that chemotherapy doesn’t just target cancer cells – it also disrupts how genes are regulated in the brain, specifically in the prefrontal cortex, the area responsible for decision-making and executive function.”

—Karen Hubbard, Study Co-Lead and Professor of Biology

Unlocking Biological Mechanisms for “Chemo Brain”

This research provides a tangible biological explanation for the long-term cognitive challenges, commonly known as “chemo brain,” that many cancer patients, particularly breast cancer survivors, report even years after completing treatment. The study’s insights could pave the way for identifying vulnerable patients.

Furthermore, the findings may guide the development of novel epigenetic therapies. Interventions targeting DNMT or HDAC enzymes, for instance, could potentially prevent or even reverse chemotherapy-induced cognitive deficits.

The CCNY team is continuing its investigation, focusing on RNA-binding proteins. These proteins are known to influence brain aging and are being examined in the prefrontal cortex and hippocampus of the chemotherapy-treated rats. This ongoing work aims to further elucidate how chemotherapy disrupts molecular pathways associated with cognitive decline.

According to the National Cancer Institute, cognitive impairment can affect up to 75% of cancer patients, with symptoms including memory problems, difficulty concentrating, and reduced processing speed, often persisting long after treatment concludes. This study offers a significant step toward understanding and mitigating these effects.

Future Directions and Collaboration

The research team includes CCNY members Shami Chakrabarti, Chanchal Wagh, Ciara Bagnall-Moreau (also with the Institute of Molecular Medicine, The Feinstein Institute of Medical Research), Fathema Uddin, Joshua Reiser, and Kaliris Salas-Ramirez (CUNY School of Medicine). Collaborators also include Tim Ahles from Memorial Sloan Kettering Cancer Center.

August 1, 2025 0 comments

Technology

High-Resolution Microscope Reveals Neurovascular Dynamics in Awake Mice

by Rachel Kim – Technology Editor July 24, 2025

written by Rachel Kim – Technology Editor

Here’s a breakdown of the provided text, focusing on the key information about the LiTA-HM technology:

What is Neurovascular Coupling (NVC)?

NVC is the process where increased neural activity leads to the dilation of nearby blood vessels.
This dilation increases blood supply to meet the higher energy demands of active neurons. NVC is crucial for normal brain function and for non-invasive brain-computer interfaces (BCIs).

The Problem with Existing Technologies:

Conventional technologies have limitations in their detection range and/or spatiotemporal resolution.
This prevents precise analysis of dynamic changes in neurons and blood vessels across the entire cortex.
these limitations hinder research into the full potential of NVC.

The Solution: The lita-HM (Linear Transducer-Array-Based Hybrid Microscope)

Developed by: A research team from the Shenzhen institute of Advanced Technology of the Chinese Academy of Sciences, led by Profs. ZHENG Hairong,LIU Chengbo,and ZHENG Wei. Published in: Science Advances on July 23.
What it does: Enables simultaneous, dynamic, high-resolution imaging of neuronal activity and microvascular behavior across the entire cortex of awake mice.

Key Technical Innovations of LiTA-HM:

high-Speed Polygon Scanning System:

For optical-resolution photoacoustic microscopy.
Significantly increases imaging speed.
Maintains system stability.

Optimized Optical Pathways:

Provide uniform 6-μm resolution.
Cover a 6.5-mm range.
Feature a flat imaging plane.
These elements are foundational for high-resolution, rapid multimodal imaging.

8-Channel Transducer Array:

Expands the imaging field of view.
Has a 6-mm detection range.
Maintains high sensitivity.
Allows the polygon scanner to operate in air,eliminating interference from coupling media without sacrificing speed or stability.

Novel Image Reconstruction Algorithm:

Uses weighted averaging and adaptive stripe filtering.
Effectively suppresses transducer-induced artifacts.
Significantly improves the signal-to-noise ratio.LiTA-HM’s Capabilities:

High-speed, large-field-of-view visualization: Of neurovascular activity in awake mice.
Captures: Capillary-scale vascular networks and single-neuron soma details.
Coverage: Across the entire cortex.
Resolution: 6-μm spatial resolution.
Field of View: 6 mm × 5 mm.
Speed: 1.25 frames per second.
Functionality: Allows real-time, full-cortex monitoring of neurovascular dynamics.Applications and Potential:

Successfully used in awake mouse experiments for brain disease models and functional imaging. Highlights its potential for advancing brain research.
Offers practical applications.
provides a new tool for non-invasive BCI data acquisition.

July 24, 2025 0 comments

Health

Blocking GAPDH aggregation protects brain cells and opens new path for stroke therapy

by Dr. Michael Lee – Health Editor July 21, 2025

written by Dr. Michael Lee – Health Editor

New Stroke Therapy Targets Protein Aggregation

Inhibiting GAPDH Could Significantly Reduce Brain Damage

A groundbreaking study suggests that blocking a specific protein’s clumping could revolutionize acute ischemic stroke treatment, offering a new avenue to mitigate devastating brain injuries.

Unlocking a Novel Therapeutic Target

Researchers have identified the protein glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as a key player in stroke-induced brain damage. When the brain suffers from a lack of blood flow followed by its restoration—a process known as ischemia-reperfusion injury—it experiences significant oxidative and nitrosative stress. This stress can lead to neuronal death.

The study, published in the journal iScience, details how GAPDH, a protein with multiple cellular roles, behaves differently under varying stress levels. Low to moderate stress prompts its movement to the cell nucleus, contributing to apoptosis, while severe stress causes it to aggregate, leading to necrosis. This aggregation phase is now seen as a critical target for intervention.

Blocking GAPDH aggregation offers a promising new path for stroke therapy by protecting brain cells.

Study Reveals Promising Results in Animal Models

To investigate this, scientists utilized a mouse model of stroke by temporarily blocking the middle cerebral artery. They observed that GAPDH aggregates began to form in the brain’s striatum approximately 12 hours after reperfusion, even before infarction became evident. This temporal relationship strongly suggests a causal link between GAPDH aggregation and subsequent brain damage.

Further experiments involved genetically modified mice engineered to express a variant of GAPDH that inhibits aggregation. These mice exhibited significantly reduced infarct volumes in both the cortex and striatum compared to their control counterparts. Their neurological function also showed marked improvement, indicating that preventing GAPDH aggregation effectively lessened the brain damage.

Pharmacological Intervention Shows Therapeutic Potential

Beyond genetic manipulation, the researchers explored pharmacological inhibition. They identified a tripeptide, GAI-17, as a potent inhibitor of GAPDH aggregation. In the MCAO mouse model, administering GAI-17 one hour before, immediately after, and twelve hours after reperfusion significantly reduced infarct volumes, particularly in the cortical penumbra—the area surrounding the core ischemic region.

Crucially, the study established a therapeutic window for GAI-17. Treatments administered up to six hours post-reperfusion demonstrated significant protective effects, improving neurological deficits. However, interventions at nine hours post-reperfusion showed no protective benefits, defining a critical window for intervention.

According to the World Health Organization, stroke is the second leading cause of death globally, responsible for approximately 6 million deaths annually (WHO). Current treatments like recombinant tissue plasminogen activator have a narrow therapeutic window of 4.5 hours, highlighting the urgent need for alternative therapies with extended efficacy.

Study Limitations and Future Directions

While promising, the research acknowledges certain limitations. The study focused exclusively on transient ischemia with reperfusion, not permanent strokes. The assessments were also short-term, up to 48 hours post-event, and did not explore long-term effects. Furthermore, potential off-target effects of GAI-17 were not fully investigated, and sex-based differences in susceptibility were not extensively studied.

Despite these limitations, the findings strongly suggest that inhibiting GAPDH aggregation represents a viable therapeutic strategy for acute ischemic stroke. This approach could offer a much-needed extension of the treatment window, potentially saving countless lives and reducing the debilitating effects of stroke.

July 21, 2025 0 comments

Health

Ultra-processed foods threaten brain health in kids and teens, review warns

by Dr. Michael Lee – Health Editor July 14, 2025

written by Dr. Michael Lee – Health Editor

Ultra-Processed Foods Threaten Developing Brains, Study Warns

Urgent Call to Rethink Maternal and Child Diets

A landmark review reveals a disturbing link between ultra-processed foods (UPFs) and significant risks to brain development, potentially amplifying the likelihood of conditions like ADHD, depression, and even dementia later in life. The findings underscore an urgent need to reassess the dietary habits of expectant mothers and children.

Concerns Over UPF Consumption Grow

Researchers in Switzerland have meticulously examined the ramifications of UPF consumption across critical developmental stages: prenatal, adolescent, and early childhood. Their findings, published in the journal Frontiers in Public Health, suggest that early exposure to these highly processed items could impede cognitive growth and elevate risks for long-term mental health challenges.

UPFs, characterized by their high content of unhealthy fats, salt, and sugar, have become ubiquitous in modern diets. While their impact on adult health is increasingly understood, the specific effects on a developing brain remain a significant concern.

The review notes that UPFs are engineered for maximum palatability and shelf-life, often at the expense of nutritional value. They frequently contain additives and byproducts from extensive processing and packaging.

In many developed nations, UPFs now constitute over half of daily dietary energy intake. This trend is also on the rise in middle-income countries, with children and adolescents showing particularly high consumption rates, a demographic highly vulnerable to nutritional deficiencies. This pattern could initiate a detrimental cycle impacting health across generations.

A new review highlights the potential dangers of ultra-processed foods for the developing brain.

Health Ramifications of UPF Diets

Extensive studies consistently associate UPFs with weight gain and obesity across all age groups. Furthermore, diets heavy in these processed items are linked to an increased risk of various cancers, cardiovascular diseases, type 2 diabetes, metabolic syndrome, and hypertension.

During pregnancy, high UPF intake has been linked to pre-eclampsia, gestational diabetes, and adverse neonatal outcomes, including congenital heart defects and premature births. Crucially, UPFs displace nutrient-dense foods, leading to micronutrient deficiencies that are particularly harmful during critical periods of rapid growth and neural maturation.

Emerging evidence also connects heavy UPF consumption with hyperactivity, attention difficulties, depression, and anxiety, potentially causing cumulative, lifelong neurocognitive harm. Deficiencies in vital nutrients like iron and zinc, often found in UPF-heavy diets, can hinder neurodevelopmental processes and cognitive functions in children.

For instance, animal studies indicate that trans-fat intake during pregnancy can trigger inflammation and memory deficits in offspring. The review also points to the role of UPFs in disrupting the gut-brain axis. Alterations in the gut microbiome due to UPFs can negatively affect the production of crucial neurotransmitters like serotonin and brain-derived neurotrophic factor (BDNF), both vital for cognitive development and mood regulation.

A concerning statistic from the UK indicates that UPFs provide 65% or more of lunchtime calories in many school meal programs, potentially entrenching poor dietary habits from a young age.

Vulnerable Stages and Brain Development

The developing brain is particularly susceptible to nutritional influences. The third trimester of pregnancy and early childhood are periods of intense plasticity, where inadequate nutrition can permanently alter brain structure and function.

Adolescence represents another critical window. The ongoing maturation of the prefrontal cortex and the mesolimbic dopamine system makes this age group more sensitive to the rewarding effects of UPFs and emotional stress.

Repeated exposure to UPFs during these formative stages can strengthen pathways associated with reward seeking while weakening inhibitory control mechanisms. This can contribute to habitual overconsumption, described in the review as “reward dysfunction.”

Ultra-processed foods threaten brain health in kids and teens, review warns — UPF consumption can have a cumulative impact across life stages, potentially leading to long-term health issues.

The widespread availability of UPFs, aggressive marketing tactics, and increased screen time collectively create an environment that promotes the consumption of energy-dense, sweet, and salty foods. Early UPF consumption can lead to chronic inflammation, persistent obesity, metabolic dysfunction, and a higher risk of mental health disorders persisting into adulthood.

Moving Forward: Policy and Prevention

The review concludes that cumulative exposure to UPFs, from fetal development through adulthood, is strongly associated with a spectrum of neurocognitive issues, ranging from early executive dysfunction to an increased risk of dementia in later life.

The authors advocate for public health interventions, including reducing the availability of UPFs, implementing clear front-of-pack food labeling, and encouraging product reformulation. Prioritizing longitudinal neuroimaging research is also recommended to establish causality and identify the most sensitive developmental periods.

Clinicians are urged to promote diets rich in fiber and minimally processed foods to support optimal brain development and long-term cognitive health.

July 14, 2025 0 comments

Newer Posts

Older Posts