DNA hydrogels are programmable 3D networks that integrate molecular recognition modules (aptamers, DNAzymes, CRISPR) to translate binding events into macroscopic material responses. The central challenge is reliably amplifying these events into quantifiable changes within complex biological matrices. Sensor behavior is governed by coupled factors: material thresholding (gel–sol transition boundaries), pore architecture and mass transport, matrix interference (nucleases, proteins, ionic strength), and readout modality constraints. This review analyzes key scientific questions connecting molecular recognition to signal transduction. We summarize progress in construction routes, functionalization strategies, biosensing applications, and principal bottlenecks in complex samples. Priority directions for clinical translation include thin-film CRISPR geometries with distance readout, wireless integration for longitudinal monitoring, and standardized matrix validation frameworks. Ultimately, translation requires not only low detection limits but also reproducible manufacturing, robust real-matrix operation, and explicit mapping between hydrogel responses and clinically relevant biomarker ranges.

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Small-molecule probes are functional organic compounds of simple structure that can selectively recognize and report changes in specific biochemical molecules within the intracellular space. In recent years, with the rapid evolution of chemical biology, rationally designed small - molecule probes have become important tools for dissecting complex cellular signaling networks. For example, when it was the 1980s, Roger Y's laboratory. Tsiendeveloped calcium ion (Ca2+) indicators such as BAPTA and Fura‑2, which pioneered Ca2+imaging technologies; Pan and colleagues emphasized in a recent review that progress over the past decade has been remarkable and that probes have been widely applied to the study of proteins, signaling pathways, and drug–target interactions.The present review comprehensively summarizes the definition and design fundamentals of small-molecule probes, paying attention to the structural design of the recognition moiety, reporter element, and linker area. It then studies major probe kinds, such as imaging probes, activity - based (active - site) probes, and bioorthogonal probes, together with representative cases. At last, it looks into the progress made in using small - molecule probes in kinase - related, Ca2+and redox signaling pathways. By arranging representative studies and commenting on them, this review points up the value of small‑molecule probes in bioimaging, proteomics, and biomarker discovery, and gives an outlook on emerging trends and challenges in probe technology.

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Hidden hunger (micronutrient deficiency) is a global public health challenge rooted in the systemic loss of nutrients within the modern food system. This paper proposes an integrated "Nutrition Chain Repair" framework aimed at rebuilding nutritional integrity from production to consumption through synergistic multi-node interventions. Based on a systematic review of 11 recent publications (2024-2025), this study identifies three key intervention nodes: At the production end, enhancing the nutritional baseline through biofortification and the development of novel resources (e.g., algal protein). In processing and delivery, applying advanced encapsulation technologies (e.g., liposomes), optimizing traditional processes (e.g., freezing), and utilizing fermentation to protect and deliver nutrients precisely. At the assessment and cognition level, there is an urgent need to reform protein evaluation standards and establish the food matrix as a core paradigm. Flavor perception is the critical bridge ensuring consumer acceptance of technological outcomes and the realization of public health benefits. This study argues that only through such cross-chain, systemic, and synergistic repair can a truly nutrition-sensitive and sustainable food system be built to eradicate hidden hunger.

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Alzheimer's disease (AD) is a severe degenerative neurological disease which leads to progressive cognitive decline and memory impairment. We have affirmed amyloid-β (Aβ) plaques and tau tangles as the primary pathological hallmarks for a long time. However, many therapeutic approaches have found out that both Aβ and tau alone have achieved little success. Increasing evidence indicates that the neuroinflammation, which primarily related with microglia and astrocytes, takes the central role of causing and exacerbating the disease. Microglia and astrocytes not only respond to Aβ and tau but also control their accumulation, propagation, and associated neurotoxicity. They are also influenced by a kind ofrisky gene related to late-onset AD calls ApoE, which can further modulate them by regulating lipid metabolism and glial responses. This review synthesizes current knowledge on the roles of microglia, astrocytes, Aβ, tau, and ApoE in AD, emphasizing their interconnected contributions to pathogenesis and therapeutic opportunities.

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