In a groundbreaking advance that merges cutting-edge computational biochemistry with innovative biological experimentation, researchers have unveiled a promising acridine-derived small molecule capable of modulating vascular endothelial growth factor (VEGF) activity. This novel compound demonstrates a profound influence on angiogenesis, as evidenced by its remarkable capacity to reduce vascularization in the chick chorioallantoic membrane (CAM) model, a well-established in vivo system for studying blood vessel formation. The implications of this discovery ripple through the realms of cancer therapy, ocular diseases, and other pathological states driven by aberrant blood vessel growth.

VEGF holds a pivotal role as a signal protein that stimulates the formation of blood vessels during both normal physiological processes and pathological conditions such as tumor growth and retinopathies. Therapeutic strategies targeting VEGF have seen extensive development, yet limitations including drug resistance and side effects demand new molecular candidates. The recent study leverages sophisticated in silico methodologies—molecular docking, dynamic simulations, and binding affinity calculations—to identify and characterize a small molecule from the acridine chemical family that interacts intimately with VEGF, subtly altering its bioactivity.

The choice to explore acridine derivatives stems from their chemical versatility and known biological activities. These planar, heterocyclic compounds have historically been employed in medicinal chemistry, often displaying anti-cancer and anti-microbial properties. In the context of VEGF inhibition, the planar structure offers a potential to engage in pi-stacking and hydrogen bonding with amino acid residues critical for VEGF receptor binding, thereby competitively or allosterically modulating function.

In silico predictions yielded compelling data: molecular docking revealed a high-affinity binding site where the acridine derivative securely associates with VEGF, primarily through hydrophobic interactions augmented by selective hydrogen bonds. Such computational insights not only illuminate the structural basis of interaction but also guide the rational design of derivatives with enhanced specificity and potency.

Transitioning from computational work to biological relevance, the study employed the CAM assay to empirically evaluate the vascular inhibitory effects of the acridine molecule. The CAM, a highly vascularized extra-embryonic membrane of the developing chick embryo, serves as an indispensable model for angiogenesis owing to its accessibility, rapid growth, and close resemblance to mammalian vascular development. Application of the small molecule resulted in a discernible reduction of new blood vessel formation, validating the computational hypothesis and underscoring the therapeutic potential of the compound.

This synchronized approach—combining in silico modeling with in vivo CAM assays—represents a paradigm shift in drug discovery, optimizing resource efficiency while enhancing predictive accuracy. Moreover, the decrease in CAM vascularization indicates a direct functional impact on endothelial cells, potentially via inhibition of VEGF signaling pathways that govern endothelial proliferation, migration, and survival.

Understanding how this acridine-derived molecule impacts VEGF at the molecular level could redefine therapeutic strategies against diseases characterized by pathological angiogenesis. Tumors exploit VEGF-mediated angiogenesis to secure their nutrient supply, enabling metastasis and growth. Inhibitors that can selectively disrupt VEGF without off-target toxicity could offer a renaissance in anticancer treatment, overcoming resistance mechanisms that curtail current therapies.

In addition to oncology, proliferative diabetic retinopathy and age-related macular degeneration represent clinical arenas where VEGF modulation has transformed patient outcomes. Yet, current anti-VEGF agents often require frequent administration and pose risks including intraocular inflammation. A novel small molecule capable of sustained or enhanced efficacy may alleviate these burdens, improving patient compliance and safety profiles.

Furthermore, the pharmacokinetic properties intrinsic to acridine derivatives might facilitate advantageous drug delivery, including tissue penetration and cellular uptake, attributes vital for clinical translation. The planar aromaticity and modifiable side chains open avenues for chemical optimization, aiming to refine solubility, stability, and target selectivity.

The integration of advanced molecular simulations with experimental verification also sets a precedent for future small-molecule discovery. The ability to virtually screen vast compound libraries for VEGF interaction prior to costly biological assays accelerates the pipeline from concept to candidate. Such methodologies promise to expand the arsenal of antiangiogenic agents, potentially uncovering molecules that act synergistically or via novel mechanisms.

Notably, the research reinforces the significance of interdisciplinary collaboration, merging computational chemistry, molecular biology, pharmacology, and developmental biology. This multifaceted strategy enhances confidence in findings and facilitates a comprehensive understanding of small molecule–protein dynamics and their biological ramifications.

The study’s revelations extend an invitation to the broader scientific community to explore acridine derivatives’ potential beyond VEGF inhibition. With structural adaptability and diverse bioactivity profiles, these compounds may address other molecular targets implicated in inflammatory, infectious, or neurodegenerative diseases, where angiogenesis or protein–ligand interactions are pivotal.

As this acridine-based compound progresses towards clinical evaluation, it will be critical to scrutinize toxicological profiles, metabolic stability, off-target effects, and effective dosing regimens. The translational journey necessitates balancing efficacy with patient safety, a formidable yet attainable goal given the compound’s targeted action and promising preliminary data.

In conclusion, the synergistic study that couples in silico molecular modeling with the CAM assay sets a milestone in angiogenesis research. The identification of a small molecule that associates specifically with VEGF and demonstrates tangible reductions in vascularization heralds a new chapter in targeted therapeutic development. By refining our molecular toolbox against angiogenic diseases, this work not only expands scientific horizons but also holds promise for improving countless lives affected by disorders of vascular dysregulation.

Subject of Research: Interaction of an acridine-derived small molecule with VEGF to inhibit angiogenesis.

Article Title: Acridine-derived small molecule associates with VEGF and is linked to reduced CAM vascularization: a combined in silico and CAM study.

Article References:
Karmakar, S., Moulik, S., Ghosh, S. et al. Acridine-derived small molecule associates with VEGF and is linked to reduced CAM vascularization: a combined in silico and CAM study. BMC Pharmacol Toxicol (2026). https://doi.org/10.1186/s40360-026-01148-6

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In a groundbreaking study poised to reshape therapeutic strategies for lung adenocarcinoma, researchers have uncovered a pivotal mechanism by which the transcription factor MYBL2 diminishes the efficacy of cisplatin chemotherapy. The study, led by Lu, Zhang, Xuzhang, and colleagues, elucidates how MYBL2 suppresses GSDME-mediated pyroptosis, a form of programmed cell death known to enhance the anti-cancer effects of chemotherapy. This novel insight, published in Cell Death Discovery, highlights the intricate interplay between oncogenic regulators and cell death pathways, offering new avenues for overcoming drug resistance in one of the most lethal forms of lung cancer.

Lung adenocarcinoma remains a formidable clinical challenge, being the most common histological subtype of non-small cell lung cancer (NSCLC). Cisplatin-based chemotherapy regimens are front-line treatments, yet their effectiveness is severely hindered by the emergence of resistance mechanisms. While traditional models have focused on apoptotic evasion, the discovery that pyroptosis—a highly inflammatory and lytic form of cell death—plays a critical role in mediating chemotherapy sensitivity has invigorated the field. Pyroptosis is executed chiefly through the action of gasdermin proteins, with GSDME garnering significant attention for its tumor-suppressive functions.

The research team embarked on an in-depth molecular investigation to decipher the relationship between MYBL2 and GSDME in lung adenocarcinoma cells subjected to cisplatin treatment. MYBL2, known as a regulator of cell cycle progression and proliferation, has been reported to be overexpressed in various cancers, correlating with poor prognosis and aggressive phenotypes. By employing a combination of genetic manipulation, transcriptomic analysis, and functional assays, the study provides compelling evidence that elevated MYBL2 expression results in the downregulation of GSDME-mediated pyroptosis, thereby enhancing cellular survival post-chemotherapy.

One of the key revelations of the study is the mechanistic insight into how MYBL2 suppresses pyroptosis. The researchers demonstrate that MYBL2 binds to the promoter regions of the GSDME gene and represses its transcriptional activation. This epigenetic modulation effectively reduces the cellular pool of GSDME, impairing the cleavage events necessary for pyroptotic execution. Consequently, lung adenocarcinoma cells with high MYBL2 expression exhibit a marked resistance to cisplatin-induced pyroptosis and maintain proliferative capacity despite cytotoxic stress.

Beyond transcriptional repression, the study further explores the downstream signaling cascades that intertwine with MYBL2 activity. Intriguingly, the data reveal that MYBL2 expression modulates the balance between apoptotic and pyroptotic pathways in a context-dependent manner. The attenuation of pyroptosis not only limits the direct killing of tumor cells but also reduces the immunogenic potential of chemotherapy. Pyroptotic cell death serves to release pro-inflammatory signals that activate immune surveillance mechanisms; thus, MYBL2-mediated suppression may contribute to an immunosuppressive tumor microenvironment.

This dual role of MYBL2 underscores its potential as a therapeutic target. The researchers propose that pharmacological or genetic inhibition of MYBL2 might restore GSDME expression and pyroptotic responsiveness, sensitizing tumors to cisplatin. Such approaches could synergize with immunotherapies, given the heightened antigen presentation and immune activation following pyroptotic cell death. Indeed, preclinical models assessing MYBL2 knockdown demonstrated increased cisplatin sensitivity and augmented immune cell infiltration, lending credence to this therapeutic strategy.

The findings also invite a re-examination of resistance paradigms in lung adenocarcinoma. Traditional studies have predominantly centered on apoptosis evasion, but this work broadens the perspective by incorporating pyroptosis as a critical determinant of chemotherapeutic outcome. The suppression of GSDME-mediated pyroptosis emerges as a previously underappreciated axis of resistance, revealing vulnerabilities that could be exploited for improved patient prognosis.

Technologically, the study utilized cutting-edge next-generation sequencing to profile transcriptomic changes associated with MYBL2 modulation. Chromatin immunoprecipitation assays provided fine-scale mapping of MYBL2 binding sites, confirming direct regulation of GSDME. Functional assays, including lactate dehydrogenase release and caspase-3 activation studies, substantiated the pyroptotic phenotype and its alteration by MYBL2. This comprehensive methodological framework validates the robustness of the findings and sets a new standard for mechanistic oncology research.

Importantly, the clinical implications of MYBL2 expression levels were examined across patient tumor samples. Higher MYBL2 correlated with diminished GSDME expression and poorer responses to cisplatin. This correlation not only serves as a prognostic biomarker but also offers a stratification strategy for personalized medicine. Patients exhibiting high MYBL2 may benefit from combination regimens aiming to restore pyroptosis or bypass MYBL2-driven blocks.

The researchers also ventured into potential feedback loops and compensatory mechanisms activated in response to MYBL2 inhibition. Early data suggest that while MYBL2 is a master regulator, tumor cells may engage alternative pathways to evade pyroptosis. This underscores the complexity of therapeutic targeting and the necessity for combination treatments addressing multiple facets of cell death resistance.

From a broader perspective, this study enriches our understanding of the functional diversity of gasdermin family members in cancer biology. Whereas GSDME has been under exploration, linking its activity explicitly to chemotherapy sensitivity through modulation by transcription factors such as MYBL2 is a paradigm shift. It raises questions about the interplay of other oncogenes and tumor suppressors in regulating pyroptosis and other non-apoptotic cell death programs.

Future research spurred by these findings will likely focus on the development of MYBL2 inhibitors or modulators capable of reinstating pyroptotic death in cancer cells. The challenge will be to achieve specificity, minimizing off-target effects given MYBL2’s role in normal cellular processes. Additionally, evaluating combinatory treatments incorporating immune checkpoint blockade, epigenetic drugs, and pyroptosis inducers could revolutionize lung adenocarcinoma therapy.

In conclusion, the study by Lu et al. marks a significant advance in the molecular oncology field by delineating how MYBL2 curtails the chemotherapeutic potential of cisplatin through suppression of GSDME-driven pyroptosis. These insights pave the way for innovative interventions targeting resistance mechanisms at the level of cell death regulation and immune engagement, ultimately aiming to improve survival outcomes for patients facing lung adenocarcinoma.

Subject of Research: Mechanisms of cisplatin resistance in lung adenocarcinoma via MYBL2 regulation of GSDME-mediated pyroptosis.

Article Title: MYBL2 impedes cisplatin sensitivity through suppressing GSDME-mediated pyroptosis in lung adenocarcinoma.

Article References:
Lu, T., Zhang, J., Xuzhang, W. et al. MYBL2 impedes cisplatin sensitivity through suppressing GSDME-mediated pyroptosis in lung adenocarcinoma. Cell Death Discov. (2026). https://doi.org/10.1038/s41420-026-03175-y

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DOI: https://doi.org/10.1038/s41420-026-03175-y

In a groundbreaking study set to reshape our understanding of metabolic diseases, researchers have uncovered a pivotal mechanism linking the impaired differentiation of adipocytes in visceral fat to the pathogenesis of metabolic dysfunction-associated steatotic liver disease (MASLD). This discovery, meticulously detailed in a forthcoming publication in Nature Communications, delivers fresh insights into the cellular dynamics that precipitate one of the most pressing health crises of the 21st century.

Metabolic dysfunction-associated steatotic liver disease, previously known by its more controversial name, non-alcoholic fatty liver disease (NAFLD), represents a spectrum of liver conditions marked by excessive fat accumulation in liver cells. This condition can progress to more severe stages, such as steatohepatitis, fibrosis, cirrhosis, and ultimately liver failure or hepatocellular carcinoma. Despite extensive research, the precise cellular and molecular contributors to its onset and progression remain incompletely understood, impeding the development of effective therapeutic strategies.

Central to this new investigation is the role of adipocytes — the fat-storing cells within adipose tissue — particularly those residing in visceral fat depots. Visceral adipose tissue, distinct from subcutaneous fat, envelopes internal organs and is metabolically active, influencing systemic inflammation and insulin resistance. The study reveals that the degree to which preadipocytes differentiate into mature, functional adipocytes within visceral fat drastically influences metabolic homeostasis and liver health.

Employing state-of-the-art single-cell RNA sequencing, combined with sophisticated lineage tracing techniques, the researchers delineated the molecular signature of adipocyte populations in human visceral fat samples. They identified a marked reduction in the differentiation capacity of progenitor cells into mature adipocytes in individuals exhibiting MASLD. This deficit in differentiation results in a dysfunctional adipose tissue microenvironment, characterized by impaired lipid storage and elevated inflammatory signaling, both of which contribute to metabolic derangements.

The mechanistic underpinnings were further elucidated through in vivo models, where genetically engineered mice with selectively impaired adipocyte differentiation in visceral fat recapitulated key features of MASLD, including hepatic steatosis and inflammation. Notably, these models highlight the crosstalk between dysfunctional adipose tissue and the liver, mediated by altered adipokine profiles and increased free fatty acid flux, reinforcing the concept that visceral fat health is intimately tied to liver disease progression.

Moreover, the work unambiguously documents the disruption of key transcriptional regulators essential for adipocyte maturation, such as PPARγ and C/EBPα, within defective visceral fat depots. This transcriptional dysregulation appears to be a linchpin of the pathological cascade, suggesting that therapeutic modulation of these pathways might restore adipocyte differentiation capacity and ameliorate metabolic dysfunction.

The inflammatory milieu generated by poorly differentiated adipocytes also plays a salient role in disease manifestation. Elevated secretion of proinflammatory cytokines, including TNF-α and IL-6, promotes systemic low-grade inflammation, a recognized driver of insulin resistance and hepatic injury. Thus, the study delineates a vicious cycle wherein impaired adipocyte maturation exacerbates inflammation, which in turn further inhibits differentiation processes, compounding metabolic impairment.

From a clinical perspective, these findings carry significant implications. The assessment of adipocyte differentiation status within visceral fat may emerge as an innovative biomarker for early MASLD risk stratification. Furthermore, interventions aimed at enhancing adipogenesis or counteracting adipose tissue inflammation could constitute novel therapeutic avenues to halt or reverse disease progression, potentially transforming patient outcomes.

This research also challenges the prevailing notion that mere adiposity is the primary determinant of metabolic risk. Instead, it posits that qualitative changes within adipose tissue, specifically differentiation defects, are critical determinants of metabolic health, inviting a paradigm shift in how obesity-related complications are conceptualized and managed.

Intriguingly, the study advocates for a refined focus on cell-specific therapies that reinvigorate the adipogenic program, possibly through pharmacologic agents targeting the implicated transcription factors or signaling pathways. This approach could offer a more precise treatment modality, contrasting with the often blunt instrument of systemic metabolic control.

In parallel, the research underscores the importance of early detection of adipose tissue dysfunction. Non-invasive imaging modalities or circulating biomarkers reflecting adipocyte differentiation status could facilitate prompt clinical intervention, mitigating liver damage before irreversible fibrosis ensues.

While the research is pioneering, certain questions remain open for future exploration. For instance, the interplay between genetic predisposition, environmental factors such as diet and physical activity, and their collective impact on adipocyte differentiation warrants further inquiry. Additionally, longitudinal studies are needed to validate whether restoring adipocyte differentiation can directly translate into clinical remission of MASLD.

In summary, this seminal work inaugurates a new chapter in metabolic disease biology by linking diminished adipocyte differentiation in visceral fat with the complex etiopathogenesis of metabolic dysfunction-associated steatotic liver disease. Its implications resonate across fundamental science and clinical practice, heralding prospects for innovative diagnostics and personalized therapeutics that may stem the burgeoning tide of liver-related metabolic disorders.

Researchers and clinicians alike are poised to benefit from these insights, which illuminate the nuanced cellular landscapes underlying MASLD and spotlight a hitherto underappreciated target: the adipocyte differentiation machinery. As this field advances, the hope is to translate these molecular discoveries into tangible health benefits for millions at risk worldwide.

Subject of Research:
Metabolic dysfunction-associated steatotic liver disease and the cellular mechanisms of adipocyte differentiation in visceral adipose tissue.

Article Title:
Decreased degree of adipocyte differentiation in visceral adipose tissue contributes to metabolic dysfunction-associated steatotic liver disease.

Article References:
Gelev, K.Z., Lee, S.H.T., Alvarez, M. et al. Decreased degree of adipocyte differentiation in visceral adipose tissue contributes to metabolic dysfunction-associated steatotic liver disease. Nat Commun (2026). https://doi.org/10.1038/s41467-026-73660-6

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In a landmark study that could fundamentally change our understanding of lung adenocarcinoma progression and treatment resistance, researchers have uncovered the pivotal role of the transcription factor C/EBPγ in driving epithelial-mesenchymal transition (EMT) and enhancing DNA double-strand break repair mechanisms. This groundbreaking discovery, detailed in a recent publication in Cell Death Discovery, sheds new light on how cancer cells acquire invasive properties while simultaneously fortifying their genomic integrity against therapeutic assaults.

Lung adenocarcinoma, the most common subtype of non-small cell lung cancer, remains a formidable clinical challenge due to its high propensity for metastasis and acquired resistance to conventional DNA-damaging therapies such as radiation and chemotherapy. The biological processes that enable cancer cells to transition from a stationary epithelial state to a mobile mesenchymal form—thereby increasing their metastatic potential—have long been connected to poor prognosis. However, the molecular underpinnings orchestrating this epithelial-mesenchymal transition, especially in the context of DNA damage repair pathways, have been only partially understood until now.

The study rigorously investigated the role of CCAAT/enhancer-binding protein gamma (C/EBPγ), a member of the C/EBP family of transcription factors, widely implicated in cellular differentiation and inflammatory responses. What sets this research apart is its dual focus on how C/EBPγ not only governs phenotypic plasticity through EMT but also actively modulates the DNA repair machinery, particularly the critical repair of DNA double-strand breaks (DSBs). This dual functionality positions C/EBPγ as a potential master regulator in lung adenocarcinoma malignancy and therapy resistance.

Using a combination of molecular biology techniques, including chromatin immunoprecipitation followed by sequencing (ChIP-seq), the researchers mapped the genome-wide binding sites of C/EBPγ in lung adenocarcinoma cell lines. They found that C/EBPγ directly binds to and regulates the promoters of key genes involved in EMT, including those coding for mesenchymal markers such as N-cadherin and vimentin, while repressing epithelial markers like E-cadherin. This transcriptional regulation promotes the cells’ detachment from the primary tumor mass and facilitates their migration and invasion into surrounding tissues.

The discovery did not stop there. Intriguingly, the team observed that cells with elevated C/EBPγ expression exhibited upregulated components of the non-homologous end joining (NHEJ) pathway, the primary mechanism by which most mammalian cells repair DNA double-strand breaks. Enhanced expression of DNA repair proteins like DNA-PKcs and Ku70/80 suggested that C/EBPγ boosts the capacity of cancer cells to withstand genotoxic stress. This finding has significant clinical implications because it hints that C/EBPγ-positive tumors may be intrinsically more resistant to therapies designed to induce lethal DNA breaks.

Functional assays confirmed these observations: knocking down C/EBPγ in lung adenocarcinoma cells led to impaired EMT, reduced migratory abilities, and a marked decrease in the efficiency of DNA DSB repair after radiation treatment. Conversely, overexpression of C/EBPγ accelerated EMT and conferred resistance to DNA-damaging agents, underscoring its potential as a prognostic marker and therapeutic target.

At the molecular level, the interaction between C/EBPγ and other key transcription factors was also probed. The study highlighted how C/EBPγ cooperates with Snail and Twist, two well-known EMT-inducing factors, forming a transcriptional network that amplifies the mesenchymal gene expression program. This cooperation extends to the regulation of DNA repair genes, illustrating a complex crosstalk between the phenotypic plasticity of cancer cells and their genomic maintenance systems.

Another fascinating aspect uncovered by the research involves the epigenetic landscape. C/EBPγ was shown to recruit chromatin remodeling complexes to EMT and DNA repair gene loci, facilitating an open chromatin state conducive to active transcription. These epigenetic modifications further stabilize the mesenchymal state and reinforce the capacity for DNA repair, making cancer cells more adaptable and resilient.

The clinical relevance of these findings was bolstered by analyses of patient-derived lung adenocarcinoma samples. Higher levels of C/EBPγ correlated with advanced tumor stages, increased metastasis, and poorer overall survival, underscoring the translational potential of targeting this factor. Moreover, the research team suggested that pharmacological inhibition of C/EBPγ or its downstream effectors might sensitize tumors to DNA-damaging therapies, paving the way for novel combination treatments.

From a therapeutic standpoint, this study opens intriguing possibilities. Inhibitors designed to disrupt the function or expression of C/EBPγ could not only prevent EMT-mediated metastasis but also cripple the DNA repair defenses of cancer cells, rendering them vulnerable to radiation and chemotherapy. Such dual-action therapeutics would represent a paradigm shift, addressing both the invasive capacity and therapeutic resistance of lung cancer.

Furthermore, the insights gained about C/EBPγ’s interactions with chromatin remodeling complexes and transcriptional networks provide promising avenues for drug discovery. Epigenetic modulators that reverse the chromatin changes induced by C/EBPγ may complement direct inhibitors, creating multi-pronged strategies to thwart cancer progression.

This research also raises provocative questions for future exploration. For instance, understanding how C/EBPγ expression is regulated within the tumor microenvironment or by oncogenic signaling pathways could illuminate the signals that drive aggressive phenotypes. Additionally, it prompts investigation into whether similar mechanisms operate in other cancer types, potentially broadening the impact of these findings.

In summary, the identification of C/EBPγ as a critical driver of both epithelial-mesenchymal transition and enhanced DNA double-strand break repair pathways presents a significant advance in lung adenocarcinoma biology. It links cellular plasticity directly with genomic stability strategies, underscoring the adaptability of cancer cells and highlighting a crucial vulnerability.

As lung adenocarcinoma continues to challenge clinicians with its aggressive nature and resistance to conventional therapies, these findings illuminate new molecular targets and strategies. The prospect of therapies that can simultaneously inhibit metastasis and sensitize tumors to DNA damage could revolutionize patient outcomes, transforming lung cancer from a largely intractable disease into one that can be effectively managed or even cured.

Given the compelling data presented and the potential clinical applications, this study is poised to stimulate extensive research and drug development efforts aimed at exploiting C/EBPγ’s dual role. It heralds a future where the genetic and phenotypic malleability of lung adenocarcinoma cells can be manipulated for therapeutic benefit, greatly enhancing the arsenal against one of the most lethal human cancers.

Subject of Research:
Role of C/EBPγ in inducing epithelial-mesenchymal transition and facilitating DNA double-strand break repair in lung adenocarcinoma cells.

Article Title:
C/EBPγ induces epithelial-mesenchymal transition and facilitates DNA double-strand break repair in lung adenocarcinoma cells.

Article References:
Terashima, M., Suzuki, R., Suphakhong, K. et al. C/EBPγ induces epithelial-mesenchymal transition and facilitates DNA double-strand break repair in lung adenocarcinoma cells. Cell Death Discov. (2026). https://doi.org/10.1038/s41420-026-03181-0

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DOI:
https://doi.org/10.1038/s41420-026-03181-0