Monkfruit turns out to be more than sweet, it’s packed with hidden compounds linked to health. Luohan Guo (Siraitia grosvenorii), commonly called monkfruit, is a long living vine that belongs to the gourd family, which also includes familiar plants like squash, melons, and cucumbers. It is native to China, where it has been grown and […]
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Monkfruit Has a Powerful Side Scientists Are Uncovering – Science News
Restoring Immunological Tolerance via Dendritic Cells in Rheumatoid Arthritis – Research
Rheumatoid arthritis (RA) represents a major global public health challenge, with approximately 1% of the world’s population suffering from this disease. In the absence of a cure, patients require ongoing and very often lifelong treatment. While environmental, genetic, and epigenetic factors have all been linked to the development of RA, a key, universally accepted initiating factor in disease development is the loss of immunological tolerance to self-antigens. Currently, most treatment approaches utilise agents that suppress the immune system or inflammatory response. However, there is no currently available treatment to re-establish self-tolerance, the key driving factor in the initiation of the disease. In this review, we will explore how peripheral tolerance mechanisms fail in RA, leading to disease initiation and progression. We will explore how dendritic cells (DCs), a central and nonredundant cell type in maintaining immune tolerance, contribute to RA and discuss molecular strategies to switch these immunogenic and self-reactive cells to tolerogenic cells. Finally, in addition to understanding the fundamental mechanisms of how peripheral tolerance mechanisms are lost, it is also important to know where this dysregulation occurs. Therefore, in this review, we will also discuss emerging research on sites of disease initiation in the context of tolerance.
Keywords:
dendritic cells; immune regulation; rheumatology; tolerance.
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This Forgotten Cancer Vaccine’s Results Were So Unusual Scientists Revisited It 20 Years Later – Science News
New research suggests that a breast cancer vaccine developed decades ago may have triggered a lasting immune memory response that can now be significantly boosted by a newly developed antibody. More than two decades ago, a small group of women with advanced breast cancer took part in a clinical trial testing a vaccine. All of […]
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Restoring Immunological Tolerance via Dendritic Cells in Rheumatoid Arthritis – Research
Rheumatoid arthritis (RA) represents a major global public health challenge, with approximately 1% of the world’s population suffering from this disease. In the absence of a cure, patients require ongoing and very often lifelong treatment. While environmental, genetic, and epigenetic factors have all been linked to the development of RA, a key, universally accepted initiating factor in disease development is the loss of immunological tolerance to self-antigens. Currently, most treatment approaches utilise agents that suppress the immune system or inflammatory response. However, there is no currently available treatment to re-establish self-tolerance, the key driving factor in the initiation of the disease. In this review, we will explore how peripheral tolerance mechanisms fail in RA, leading to disease initiation and progression. We will explore how dendritic cells (DCs), a central and nonredundant cell type in maintaining immune tolerance, contribute to RA and discuss molecular strategies to switch these immunogenic and self-reactive cells to tolerogenic cells. Finally, in addition to understanding the fundamental mechanisms of how peripheral tolerance mechanisms are lost, it is also important to know where this dysregulation occurs. Therefore, in this review, we will also discuss emerging research on sites of disease initiation in the context of tolerance.
Keywords:
dendritic cells; immune regulation; rheumatology; tolerance.
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One Flour Swap Can Transform Your Sourdough – Science News
The flour you choose helps decide which microbes run your sourdough and how it tastes. Sourdough starter is made from just flour and water, yet it supports a complex process that bakers rely on every day. Beyond baking, it also offers scientists a unique window into how microorganisms interact and evolve. The familiar chewiness and […]
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Reversible Metal Coordination Switch Enables Activatable Sonodynamic Therapy via Dual-Death and Immune Synergy – Research
Sonodynamic therapy (SDT) holds great potential for disease treatment, yet its efficacy is limited by constitutive reactive oxygen species (ROS) generation and poor selectivity. Herein, we report a generalizable strategy using reversible metal-ion coordination to regulate the sonodynamic activity of semiconducting polymers (SPs). A diketopyrrolopyrrole (DPP)-based polymer (SPC) serves as the coordination scaffold, where binding with transition metal ions (Cu2+, Co2+, Zn2+, Fe3+) redistributes electron density and increases the singlet-triplet energy gap (ΔEST), thereby effectively suppressing ROS generation. Among them, Cu2+ is selected as a model ion due to its reductive responsiveness to glutathione (GSH) in the tumor microenvironment (TME). This enables SPCu to remain inactive during systemic circulation and become selectively reactivated within the TME. Released copper further induces mitochondrial dysfunction and cuproptosis, synergizing with ultrasound-triggered ROS-driven PANoptosis. Together, this dual-death mechanism elicits robust tumor ablation, immunogenic cell death, and immune cell activation, leading to systemic antitumor immunity. Collectively, this study presents a reversible, metal coordination-based platform for constructing activatable organic sonosensitizers, offering precise SDT with immuno-therapeutic synergy.
Keywords:
activatable therapy; immunotherapy; metal‐ion coordination; semiconducting polymers; sonodynamic therapy.
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Scientists Discover That Electric Fields Flip the Rules of Water Chemistry – Science News
A new study identifies how water becomes ionized under electrochemical conditions. Hydrogen is expected to play a major role in future energy systems, which makes a clear understanding of electrolysis increasingly important. Scientists at the Max Planck Institute for Polymer Research and the Yusuf Hamied Department of Chemistry at the University of Cambridge have taken […]
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Reversible Metal Coordination Switch Enables Activatable Sonodynamic Therapy via Dual-Death and Immune Synergy – Research
Sonodynamic therapy (SDT) holds great potential for disease treatment, yet its efficacy is limited by constitutive reactive oxygen species (ROS) generation and poor selectivity. Herein, we report a generalizable strategy using reversible metal-ion coordination to regulate the sonodynamic activity of semiconducting polymers (SPs). A diketopyrrolopyrrole (DPP)-based polymer (SPC) serves as the coordination scaffold, where binding with transition metal ions (Cu2+, Co2+, Zn2+, Fe3+) redistributes electron density and increases the singlet-triplet energy gap (ΔEST), thereby effectively suppressing ROS generation. Among them, Cu2+ is selected as a model ion due to its reductive responsiveness to glutathione (GSH) in the tumor microenvironment (TME). This enables SPCu to remain inactive during systemic circulation and become selectively reactivated within the TME. Released copper further induces mitochondrial dysfunction and cuproptosis, synergizing with ultrasound-triggered ROS-driven PANoptosis. Together, this dual-death mechanism elicits robust tumor ablation, immunogenic cell death, and immune cell activation, leading to systemic antitumor immunity. Collectively, this study presents a reversible, metal coordination-based platform for constructing activatable organic sonosensitizers, offering precise SDT with immuno-therapeutic synergy.
Keywords:
activatable therapy; immunotherapy; metal‐ion coordination; semiconducting polymers; sonodynamic therapy.
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Circular RNAs in human biology: from splicing noise to master regulators – Research
Circular RNAs (circRNAs) are covalently closed RNA transcripts produced by back-splicing. First identified in plant viroid in 1976, they were long regarded as “splicing noise” or transcriptional byproducts. However, high-throughput sequencing has revealed thousands of circRNAs in eukaryotic cells, indicating that they are widespread and conserved. These molecules lack 5′ caps and 3′ poly(A) tails, making them resistant to exonucleases. Their circular structure confers exceptional stability, and many circRNAs are expressed in a tissue-specific manner, making them attractive biomarkers. Functionally, circRNAs regulate gene expression at multiple levels. Many act as “sponges” for microRNAs or RNA-binding proteins, modulating mRNA stability and translation; others influence transcription, alternative splicing, or chromatin architecture, and some can be translated into peptides. In human biology, circRNAs have diverse roles: dysregulated circRNAs contribute to tumorigenesis and shape the tumor microenvironment; they are abundant in the brain and implicated in neurodevelopment and neurodegenerative diseases; and they modulate immune responses (for example, via T cells, NK cells, and macrophages). Experimentally, circRNAs are detected by RNase R-enriched RNA sequencing and bioinformatics pipelines that identify unique back-splice junction reads. Predicted circRNAs are then validated by RT-PCR across the circular junction. The stability and versatility of circRNAs have inspired therapeutic applications, such as engineered circRNA vaccines or miRNA sponges. Overall, these findings underscore that circRNAs constitute a powerful and versatile class of gene regulators with significant diagnostic and therapeutic potential, although translating this potential into clinical success requires overcoming current challenges. Nonetheless, significant challenges in delivery, specificity, and immunogenicity remain to be addressed before clinical translation.
Keywords:
Back-splicing; Bioinformatics; Circular RNA; Immunotherapy; MicroRNA sponge.
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Scientists Uncover Potential “Two-in-One” Treatment for Diabetes and Heart Disease – Science News
The experimental drug IC7Fc reduces artery-clogging fats and inflammation in mice, pointing to a potential new strategy for preventing heart disease. Earlier work linked the experimental drug ‘IC7Fc’ to improvements in type 2 diabetes, and new research now points to a possible role in cardiovascular health as well. Scientists report that the compound may lower […]
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