Ultrabright and ultrafast afterglow imaging in vivo via nanoparticles made of trianthracene derivatives.

Low sensitivity, photobleaching, high-power excitation and long acquisition times constrain the utility of afterglow luminescence. Here we report the design and imaging performance of nanoparticles made of electron-rich trianthracene derivatives that, on excitation by room light at ultralow power (58 μW cm), emit afterglow luminescence at ~500 times those of commonly used organic afterglow nanoparticles. The nanoparticles' ultrabright afterglow allowed for deep-tissue imaging (up to 6 cm), for ultrafast afterglow imaging (at short acquisition times down to 0.

Responsive Magnetic Particle Imaging Tracer: Overcoming "Always-On" Limitation, Eliminating Interference, and Ensuring Safety in Adaptive Therapy.

Magnetic particle imaging (MPI) has emerged as a novel technology utilizing superparamagnetic nanoparticles as tracers, essential for disease diagnosis and treatment guidance in preclinical animal models. Unlike other modalities, MPI provides high sensitivity, deep tissue penetration, and no signal attenuation. However, existing MPI tracers suffer from "always-on" signals, which complicate organ-specific imaging and hinder accuracy.

Imaging-guided companion diagnostics in radiotherapy by monitoring APE1 activity with afterglow and MRI imaging.

Companion diagnostics using biomarkers have gained prominence in guiding radiotherapy. However, biopsy-based techniques fail to account for real-time variations in target response and tumor heterogeneity. Herein, we design an activated afterglow/MRI probe as a companion diagnostics tool for dynamically assessing biomarker apurinic/apyrimidinic endonuclease 1(APE1) during radiotherapy in vivo.

Enhancing Fractionated Cancer Therapy: A Triple-Anthracene Photosensitizer Unleashes Long-Persistent Photodynamic and Luminous Efficacy.

Conventional photodynamic therapy (PDT) is often limited in treating solid tumors due to hypoxic conditions that impede the generation of reactive oxygen species (ROS), which are critical for therapeutic efficacy. To address this issue, a fractionated PDT protocol has been suggested, wherein light irradiation is administered in stages separated by dark intervals to permit oxygen recovery during these breaks. However, the current photosensitizers used in fractionated PDT are incapable of sustaining ROS production during the dark intervals, leading to suboptimal therapeutic outcomes (Table S1).

Noninvasive Imaging of Tumor Glycolysis and Chemotherapeutic Resistance via De Novo Design of Molecular Afterglow Scaffold.

Chemotherapeutic resistance poses a significant challenge in cancer treatment, resulting in the reduced efficacy of standard chemotherapeutic agents. Abnormal metabolism, particularly increased anaerobic glycolysis, has been identified as a major contributing factor to chemotherapeutic resistance. To address this issue, noninvasive imaging techniques capable of visualizing tumor glycolysis are crucial.

Emerging biomedical imaging-based companion diagnostics for precision medicine.

The tumor heterogeneity, which leads to individual variations in tumor microenvironments, causes poor prognoses and limits therapeutic response. Emerging technology such as companion diagnostics (CDx) detects biomarkers and monitors therapeutic responses, allowing identification of patients who would benefit most from treatment. However, currently, most US Food and Drug Administration-approved CDx tests are designed to detect biomarkers and , making it difficult to dynamically report variations of targets .

The rational design of nanozymes for imaging-monitored cancer therapy.

Nanozymes are nanoscale materials that display enzyme-like properties, which have been improved to eliminate the limitations of natural enzymes and further broaden the use of conventional artificial enzymes. In the last decade, the research and exploration of nanozymes have attracted considerable attention in the chemical and biological fields, especially in the fields of biomedicine and tumor therapy. To date, plenty of nanozymes have been developed with the single or multiple activities of natural enzymes, including peroxidase (POD), catalase (CAT), superoxide dismutase (SOD), glucose oxidase (GOx).

Organic Afterglow Nanoparticles in Bioapplications.

Organic afterglow nanoparticles are unique optical materials that emit light long after cessation of excitation. Due to their advantages of no need for real-time light excitation, avoiding autofluorescence, low imaging background, high signal-to-background ratio, deep tissue penetration, and high sensitivity, afterglow imaging technology has been widely used in cell tracking, biosensing, cancer diagnosis, and cancer therapy, which provides an effective technical method for the acquisition of molecular information with high sensitivity, specificity and real-time at the cellular and living level. In this review, we summarize and illustrate the recent progress of organic afterglow imaging, focusing on the mechanism of organic afterglow materials and their biological application.

Semiconducting Polymer Nanoparticles-Manganese Based Chemiluminescent Platform for Determining Total Antioxidant Capacity in Diabetic Mice.

The total antioxidant capacity (TAC) is a key indicator of the body's resistance to oxidative stress injury in diabetic patients. The measurement of TAC is important for effectively evaluating the redox state to prevent and control the occurrence of diabetes complications. However, there is a lack of a simple, convenient, and reliable method to detect the total antioxidant capacity in diabetes.

Prediction Models for Sleep Quality Among College Students During the COVID-19 Outbreak: Cross-sectional Study Based on the Internet New Media.

Background: COVID-19 has been reported to affect the sleep quality of Chinese residents; however, the epidemic's effects on the sleep quality of college students during closed-loop management remain unclear, and a screening tool is lacking.

Objective: This study aimed to understand the sleep quality of college students in Fujian Province during the epidemic and determine sensitive variables, in order to develop an efficient prediction model for the early screening of sleep problems in college students.

Methods: From April 5 to 16, 2022, a cross-sectional internet-based survey was conducted.

Zinc-Carnosine Metallodrug Network as Dual Metabolism Inhibitor Overcoming Metabolic Reprogramming for Efficient Cancer Therapy.

The targeting of tumor metabolism as a novel strategy for cancer therapy has attracted tremendous attention. Herein, we develop a dual metabolism inhibitor, Zn-carnosine metallodrug network nanoparticles (Zn-Car MNs), which exhibits good Cu-depletion and Cu-responsive drug release, causing potent inhibition of both OXPHOS and glycolysis. Notably, Zn-Car MNs can decrease the activity of cytochrome c oxidase and the content of NAD, so as to reduce ATP production in cancer cells.

Precisely controlling the cellular internalization of DNA-decorated semiconductor polymer nanoparticles for drug delivery.

Nonspecific adhesivity of nanoparticles to cells is regarded as a significant issue of nanomedicine, which brings about many serious drawbacks in applications, including low detection sensitivity, non-targeted biotoxicity and poor diagnostic accuracy. Here, we propose for the first time, DNA-decorated semiconductor polymer nanoparticles (SPN-DNAs), whose adhesivity can be significantly alleviated by controlling the density and thickness of DNA layers. This property is demonstrated to be independent of external conditions such as temperature, concentration, incubation time, ionic strength and cell lines.

A novel afterglow nanoreporter for monitoring cancer therapy.

Immunogenic cell death (ICD)-associated immunogenicity evoked through reactive oxygen species (ROS) is an efficient way to fight against the immune-dysfunctional microenvironment, so as to provoke potent anti-tumor immunity. However, the unknown ROS dose during cancer therapies may induce adverse immune responses (e.g.

Concomitant Diseases and Co-contribution on Progression of Liver Stiffness in Patients with Hepatitis B Virus Infection.

Background: The association between hepatitis B and concomitant diseases, such as fatty liver, T2DM, MetS, and Hp infection, remains unclear.

Aim: The present study was to illustrate the association and explore the co-contribution on abnormal transaminase and progression of liver stiffness.

Methods: A total of 95,998 participants underwent HBsAg screening in West China Hospital from 2014 to 2017.

Overcoming Hypoxia-Induced Ferroptosis Resistance via a F/ H-MRI Traceable Core-Shell Nanostructure.

Lipid peroxides accumulation induced ferroptosis is an effective cell death pathway for cancer therapy. However, the hypoxic condition of tumor microenvironment significantly suppresses the efficacy of ferroptosis. Here, we design a novel nanoplatform to overcome hypoxia-induced ferroptosis resistance.

Metal-fluorouracil networks with disruption of mitochondrion enhanced ferroptosis for synergistic immune activation.

Ferroptosis drugs inducing cancer immunogenic cell death (ICD) have shown the potential of immunotherapy . However, the current ferroptosis drugs usually induce the insufficient immune response because of the low ROS generation efficiency. Herein, we design zinc-fluorouracil metallodrug networks (Zn-Fu MNs), by coordinating Zn and Fu via facile one-pot preparation, to inactivate mitochondrial electron transport for enhanced ROS production and immune activation.

Association of serum pepsinogens and gastrin-17 with infection assessed by urea breath test.

Background: Association of gastric atrophy or cancer with levels of serum pepsinogens, gastrin-17 and anti- IgG antibody have been extensively studied. However, the association of serum pepsinogen and gastrin-17 with infection has not been studied in a large population.

Aim: To investigate the impact of infection on serum levels of pepsinogens and gastrin-17.

Abnormal transaminase and lipid profiles in coexisting diseases in patients with fatty liver: a population study in Sichuan.

Among chronic liver diseases, fatty liver has the highest incidence worldwide. Coexistence of fatty liver and other chronic diseases, such as diabetes, hepatitis B virus (HBV) and Helicobacter pylori (Hp) infection, is common in clinical practice. The present study was conducted to analyze the prevalence and association of coexisting diseases in patients with fatty liver and to investigate how coexisting diseases contribute to abnormal transaminase and lipid profiles.

Two-dimensional intermetallic PtBi/Pt core/shell nanoplates overcome tumor hypoxia for enhanced cancer therapy.

The design of multifunctional nanoplatforms is of great importance for improving hypoxia-induced therapeutic outcomes, especially for overcoming radiotherapy (RT) tolerance. Here, two-dimensional intermetallic PtBi/Pt nanoplates (PtBi NPs) were designed as a therapeutic platform to in situ generate oxygen, and thereby overcome tumor hypoxia for boosting photothermal/radiotherapy (PTT/RT). With high X-ray attenuation coefficient, PtBi NPs exhibited outstanding radiotherapy sensitization characteristics.

Elevated thyroid-stimulating hormone levels are associated with poor sleep: a cross-sectional and longitudinal study.

Purpose: Poor sleep accompanied by elevated TSH (thyroid stimulating hormone) levels is not uncommon since TSH secretion is controlled by the circadian rhythm. However, the relationship between poor sleep and TSH elevation is unclear; hence, we aimed to elucidate this relationship by conducting a cross-sectional and longitudinal study.

Methods: Participants with isolated elevated (N = 168) and normal (N = 119) TSH concentrations were recruited, and the Pittsburgh Sleep Quality Index (PSQI) was used to assess the sleep status.

Nursing students' attitudes, knowledge and willingness of to receive the coronavirus disease vaccine: A cross-sectional study.

Aim: This study aimed to investigate the knowledge, attitudes and willingness of nursing students to receive the coronavirus disease (COVID-19) vaccine and the influencing factors.

Background: Vaccination is one of the most effective measures to prevent COVID-19, but the vaccination acceptance rate varies across countries and populations. As trustworthy healthcare providers, nursing students' attitudes, knowledge and willingness to receive the COVID-19 vaccine may greatly affect the present and future vaccine acceptance rates of the population; however, studies related to the vaccine acceptance rates among nursing students are limited.

Cyclic Amplification of the Afterglow Luminescent Nanoreporter Enables the Prediction of Anti-cancer Efficiency.

We developed a cyclic amplification method for an organic afterglow nanoreporter for the real-time visualization of self-generated reactive oxygen species (ROS). We promoted semiconducting polymer nanoparticles (PFODBT) as a candidate for emitting near-infrared afterglow luminescence. Introduction of a chemiluminescent substrate (CPPO) into PFODBT (PFODBT@CPPO) resulted in a significant enhancement of afterglow intensity through the dual cyclic amplification pathway involving singlet oxygen ( O ).

Tumor-Specific Multipath Nucleic Acid Damages Strategy by Symbiosed Nanozyme@Enzyme with Synergistic Self-Cyclic Catalysis.

The high proliferation efficiency, redox imbalance, and elevated nucleic acid repair capabilities of tumor cells severely restrict the theranostic efficacy. Selectively interference chaotic tumors with devastating nucleic acid damages (NUDs) properties are expected to overcome theranostic barriers. Here, an exquisite catalytic-based strategy with comprehensive NUDs mechanisms is demonstrated.