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While high-spin carbon-based polyradicals exhibit significant potential for applications in quantum information storage and sensing, their application is hampered by limited structural diversity and chemical instability. Here, the authors report the synthesis and isolation of a stable nonalternant nanographene with a triplet ground state.

Immune checkpoint inhibitors have shown promise in tumour immunotherapy but resistance has been seen. Here using pre-treatment hepatocellular carcinoma patient biopsies from patients scheduled for immunotherapy, the authors implicate BCL9 and show that a BCL9-targeting peptide promotes anti-tumour immunity in mouse models through targeting macrophages and promoting anti-tumour T cell responses.

Particles produced by intense biomass burning can be transported, potentially by deep convection, in large numbers to the lower stratosphere, changing the stratospheric aerosol layer’s chemical and radiative properties, according to in situ measurements during an active fire season.

A computational method designs receptors called T-SenSERs, which have predictable signalling responses to tumour microenvironment soluble factors and can be co-expressed with conventional CARs in T cells to enhance their therapeutic activity.

Koina is an open-source, online platform that simplifies access to machine learning models in proteomics, enabling easier integration into analysis tools and helping researchers adopt and reuse ML models more efficiently.

The synthesis of crystalline 2D polymers typically relies on reversible dynamic covalent reactions, but achieving 2D polymers through irreversible carbon-carbon coupling reactions remains a formidable challenge. Here, the authors present an on-liquid surface synthesis method for constructing diyne-linked 2D polymers.

Long-lasting oxygen catalysts are crucial for rechargeable zinc-air batteries. Here, the authors report that placing tungsten atoms next to iron atoms within N₄ units creates durable Fe-N₄/W-N₄ diatomic sites, enabling a zinc-air battery to cycle reliably for more than 10,000 h.

The synthesis of atom-thin amorphous films remains challenging as their thermodynamically favourable grains are neither two dimensional nor layered. Here a droplet-driven nanoribbon-to-film growth strategy is reported to achieve amorphous metal chalcogenides at the single-layer limit.

The role of the complement system (CS) - part of the immune system - in pancreatic ductal adenocarcinoma (PDAC) remains underexplored. Here, the authors evaluate the association of genetic variants in CS-related genes with PDAC risk, and explore their potential role in prognosis and immune infiltration.

Intercalating alkali metals into picene—a hydrocarbon with five linearly fused benzene rings—results in superconducting materials. Now, alkali-metal-doped phenanthrene, which consists of three fused benzene rings, is also found to be superconducting, opening up a broader class of organic superconductors.

This study presents a programmable mRNA nanomedicine that induces tumour-specific immunogenic cell death in immunologically cold and metastatic tumours with enhanced safety, advancing next-generation strategies for personalized cancer immunotherapy

This study presents a generative artificial intelligence approach for the high-throughput discovery of antimicrobials against multidrug-resistant bacteria.

Photovoltaic devices attached to immune cells travel through the blood to inflamed brain regions.

TEAD transcription factors are critical effectors and druggable sites of the Hippo pathway in cancer, however, the development of small molecule inhibitors and degraders remains underexplored. Here, the authors identify and characterize bifunctional IAP-based degraders targeting TEAD1 via a lipid pocket and recruit different members of the inhibitor of apoptosis proteins (IAPs) family, offering a comprehensive toolkit for structural, biophysical and cellular profiling.

Topological states are exploited based on crystalline symmetry, but under artificial gauge fields, symmetries may satisfy projective algebras, which remains less studied. Here, the authors reveal that projective symmetry algebra leads to momentum-space nonsymmorphic symmetry, resulting in new topological states over a momentum-space Klein bottle.

Authors use a high-entropy engineering approach to produce fully amorphous BiTO films by exfoliation and annealing, creating crystalline regions, leading to flexible ceramics with dielectric properties.

Tilt-corrected bright-field scanning transmission electron microscopy offers enhanced cryogenic electron microscopy contrast and substantial improvement in dose efficiency for thick samples such as bacterial cells and large organelles, while still being able to perform single-particle analysis.

Standard approaches for identifying pleiotropic genetic variants may lead to spurious results. Here the authors present a new statistical method and show that it uncovers five genes linked to metabolites in METSIM participants, which were previously undetected by existing methods.

The lack of reliable coating methods for amorphous zeolitic imidazolate framework (aZIF) materials hinders their development for applications such as photolithography and separation membranes. Supported by computational fluid dynamics modeling, the authors develop a spin-coating technique to deposit aZIF films from dilute precursors and demonstrate their wafer-scale use in advanced lithographic processes.

Correlated errors coming from leakage out of the computational subspace are an obstacle to fault-tolerant superconducting circuits. Here, the authors use a multi-level reset protocol to improve the performances of a bit-flip error correcting code by reducing the magnitude of correlations.

Measurements of the proton’s spin structure in experiments scattering a polarized electron beam off polarized protons in regions of low momentum transfer squared test predictions from chiral effective field theory of the strong interaction.

A connectome of the right optic lobe from a male fruitfly is presented together with an extensive collection of genetic drivers matched to a comprehensive neuron-type catalogue.

The origin of the magnetism in manganese-doped gallium arsenide has been the subject of much debate. Now, hard X-ray angle-resolved photoemission has been used to probe the electronic structure of this material and clarify the mechanism through which the magnetism arises.

Resonant X-ray excitation of the  ⁴⁵Sc nuclear isomeric state was achieved by irradiation of a Sc-metal foil with 12.4-keV photon pulses from a state-of-the-art X-ray free-electron laser, allowing a high-precision determination of the transition energy.

Laser-plasma accelerators can produce giga electronvolt energy electrons over centimetre scales, but their properties depend on the initial injection into the accelerator. Corde et al.study self-injection of electrons into the plasma wake and identify both transverse and longitudinal injection mechanisms.

Replacing animal feathers and wool with synthetic materials can ameliorate the ethical and environmental issues associated with the production of clothing designed to retain warmth. Here the authors present synthetic nanofibre textiles that combine wearability, comfort, lightness and thermal insulation.

In ABA trilayer graphene, a temperature gradient generates a transverse voltage that scales quadratically with the gradient and reaches an effective Nernst coefficient of 300 µV K⁻¹ near the charge neutrality point.

An EC-NBI-based CAD system with advanced multi-stage pre-training fills endoscopy’s real-time diagnosis gap for colorectal lesions. It was shown to outperform other supervised methods and guides real-time biopsies.

The detection and modelling of nine X-ray quasi-periodic eruptions from a nearby tidal disruption event shows that these eruptions arise in accretion disks around massive black holes, left behind by tidally disrupted stars, and that an orbiting body colliding with this disk is a plausible explanation for the X-ray variability.

The joint analysis of datasets from NOvA and T2K, the two currently operating long-baseline neutrino oscillation experiments, provides new constraints related to neutrino masses and fundamental symmetries.

Here, the authors show that KDM2A regulates cell cycle progression, modulation of H3K36me2 and H3K27me3 chromatin states and gene repression which are critical for survival of differentiating spermatogonia. KDM2A regulates progression through meiosis as well.

Nickel(II) dihalide precatalysts with bidentate nitrogen ligands are widely used in cross-coupling reactions, notably in combination with photosensitizers, forming catalytic systems that currently drive major conceptual and synthetic thrusts within organic chemistry. Here the authors show a general mechanism by which these precatalysts are converted to the reduced, catalytically active species, using a range of characterization and spectroscopic techniques.

Battery recyclability presents a sustainability challenge in materials design. Now it has been shown that aramid amphiphile self-assembly yields solid-state electrolytes with fast ion conductivity and electrochemical stability, which disassemble to the monomeric state upon solvent exposure, enabling inherently recyclable, molecularly engineered battery designs.

One of the attractions in studying oxide heterostructures is the unusual physical phenomena that they enable. It is now demonstrated that the enforced cation ordering in thin oxide superlattices leads to significantly enhanced magnetic ordering temperatures.

The nature of unconventional charge density wave in kagome metals is currently under intense debate. Here the authors report the coexistence of the 2 × 2 × 1 charge density wave in the kagome sublattice and the Sb 5p-electron assisted 2 × 2 × 2 charge density waves in CsV₃Sb₅.

Delocalized radical systems are appealing for controlling stereoselectivity in organic synthesis. Here the authors report on a Co(II)-based enantioselective radical system for the dearomative 1,7-conjugate amination of readily available 4-vinylphenols with aryl azides.

This work proposes a wet-chemical etching assisted aberration-enhanced single-pulsed femtosecond laser nanolithography, named “WEALTH”, for manufacturing small-size, large-area, deep holey nanostructures, promising for emerging nanophotonic devices.

3D x-ray diffraction (3DXRD) is a powerful technique for studying the mechanical behavior of polycrystalline materials. Historically limited to synchrotrons, here, we present the first demonstration of 3DXRD at the laboratory scale (Lab-3DXRD).

A nano-optical probe of the Purcell effect in a van der Waals waveguide is demonstrated, exploiting its highly confined infrared waveguide modes and the capacity for infrared emission in the monolayer limit of atomically layered van der Waals materials.

Experiments under upper-tropospheric conditions map the chemical formation of isoprene oxygenated organic molecules (important molecules for new particle formation) and reveal that relative radical ratios control their composition

How premature birth alters the organization of structural brain networks is unclear. Here, the authors use a generative algorithm to demonstrate that preterm infants have tighter network wiring constraints, leading to less efficient and less integrated networks compared to term infants.

The role Tibetan Plateau uplift played in Asian inland aridification remains unclear due to a paucity of accurately dated records. Here, the authors present a continuous aeolian sequence for the period >51–39 Ma, analysis of which indicates that aridification was driven by global climatic forcing rather than uplift.

Whether superconductivity coexists or competes with other types of order in unconventional superconductors is a question that has been hotly contested. An ARPES study reported by Yi et al. suggest that superconductivity and spin-density wave orders coexist and compete dynamically in Ba_1−xK_xFe₂As₂.

Weyl semimetals are interesting because they are characterized by topological invariants, but specific examples discovered to date tend to have complicated band structures with many Weyl points. Here, the authors show that TaIrTe₄ has only four Weyl points, the minimal number required by time-reversal symmetry.

Complete sequences of chromosomes telomere-to-telomere from chimpanzee, bonobo, gorilla, Bornean orangutan, Sumatran orangutan and siamang provide a comprehensive and valuable resource for future evolutionary comparisons.

Cell type labelling in single-cell datasets remains a major bottleneck. Here, the authors present AnnDictionary, an open-source toolkit that enables atlas-scale analysis and provides the first benchmark of LLMs for de novo cell type annotation from marker genes, showing high accuracy at low cost.