Cyclic di-GMP as an antitoxin regulates bacterial genome stability and antibiotic persistence in biofilms.

Biofilms are complex bacterial communities characterized by a high persister prevalence, which contributes to chronic and relapsing infections. Historically, persister formation in biofilms has been linked to constraints imposed by their dense structures. However, we observed an elevated persister frequency accompanying the stage of cell adhesion, marking the onset of biofilm development.

Response Surface Optimization of Polysaccharides from Jaboticaba (Myrciaria cauliflora [Mart.] O.Berg) Fruits: Ultrasound-Assisted Extraction, Structure Properties, and Antioxidant/Hypoglycemic Activities.

Ultrasound-assisted extraction (UAE) method proves to be more effective compared to traditional extraction methods. In the present study, response surface methodology (RSM) was used to determine the optimal process parameters for extracting polysaccharides (U-MCP) from jaboticaba fruit using UAE. The optimum extraction conditions were ultrasonic time 70 min, extraction temperature 60 °C, and power 350 W.

Drug delivery nanoparticles for preventing implant bacterial infections based on the bacteria and immunity mechanisms.

Implant dysfunction and failure during medical treatment can be attributed to bacterial infection with and , which are the prevalent strains responsible for implant infections. Currently, antibiotics are primarily used either locally or systemically to prevent and treat bacterial infections in implants. However, the effectiveness of this approach is unsatisfactory.

Microenvironment-Regulating Drug Delivery Nanoparticles for Treating and Preventing Typical Biofilm-Induced Oral Diseases.

The oral cavity comprises an environment full of microorganisms. Dysregulation of this microbial-cellular microenvironment will lead to a series of oral diseases, such as implant-associated infection caused by Staphylococcus aureus (S. aureus) biofilms and periodontitis initiated by Streptococcus oralis (S.

Lighting up metastasis process before formation of secondary tumor by phosphorescence imaging.

Metastasis is the leading cause of cancer-related deaths; until now, the detection of tumor metastasis is mainly located at the period that secondary tumors have been formed, which usually results in poor prognosis. Thus, fast and precise positioning of organs, where tumor metastases are likely to occur at its earliest stages, is essential for improving patient outcomes. Here, we demonstrated a phosphorescence imaging method by organic nanoparticles to detect early tumor metastasis progress with microenvironmental changes, putting the detection period ahead to the formation of secondary tumors.

GFNet: Automatic segmentation of COVID-19 lung infection regions using CT images based on boundary features.

In early 2020, the global spread of the COVID-19 has presented the world with a serious health crisis. Due to the large number of infected patients, automatic segmentation of lung infections using computed tomography (CT) images has great potential to enhance traditional medical strategies. However, the segmentation of infected regions in CT slices still faces many challenges.

[Construction strategies and prospect of the Global Medicinal Plant Stem Cell Bank].

Medicinal plant stem cells are separated from the meristem and vascular cambium of medicinal plants, which can produce active components for preventing and treating diseases and improving body physical functions under certain conditions. Medicinal plant stem cells come from a broad category of medicinal plants, including ethnic medicinal plants, folk medicinal plants, original plants of health products, vegetables, fruits, and other potential medicinal plants. At present, the techniques for the isolation, identification, preservation and culture of medicinal plant stem cells have become increasingly mature, and the mechanism of stem cell differentiation, growth and regulation of secondary metabolites has been studied in depth.

Nanoparticles Promote Bacterial Antibiotic Tolerance via Inducing Hyperosmotic Stress Response.

With the rapid development of nanotechnology, nanoparticles (NPs) are widely used in all fields of life. Nowadays, NPs have shown extraordinary antimicrobial activities and become one of the most popular strategies to combat antibiotic resistance. Whether they are equally effective in combating bacterial persistence, another important reason leading to antibiotic treatment failure, remains unknown.

Photothermal therapy may be a double-edged sword by inducing the formation of bacterial antibiotic tolerance.

Photothermal nanoparticles are thought to be the most suitable candidates against infectious disease by disrupting the cell membrane or inhibiting cellular metabolism. However, cells with low-metabolic activity states may be endowed with greater ability against harsh environments including antibiotic treatment. For now, it remains unexplored whether and how photothermal therapy (PTT) gives rise to bacterial antibiotic tolerance.

Mobile Phone Flashlight-Excited Red Afterglow Bioimaging.

Organic room temperature phosphorescence (RTP) materials with ultralong lifetime possess the remarkable advantage in bioimaging for elimination of background noise by characteristic time scale. However, most of RTP luminogens need to be excited by the harmful ultraviolet (UV) lamp, and exhibit green or yellow emission with shallow tissue penetration, constraining the in vivo bioimaging for further application in clinical diagnosis and pathological study. In this text, the much safer excitation process by sunlight and mobile phone flashlight is realized by organic luminogens with various electronic pull-push systems.

Preparation, characterization and biological properties of a novel bone block composed of platelet rich fibrin and a deproteinized bovine bone mineral.

Alveolar bone defects caused by tooth loss often lead to challenges in implant dentistry, with a need for development of optimal bone biomaterials to predictably rebuild these tissues. To address this problem, we fabricated a novel bone block using platelet-rich fibrin (PRF) and Deproteinized Bovine Bone Mineral (DBBM), and characterized their mechanical and biological properties. The bone block was prepared by mixing DBBM, Liquid-PRF, and Solid-PRF fragments in various combinations as follows: (1) BLOCK-1 made with Solid-PRF fragments + DBBM, (2) BLOCK-2 made with Liquid-PRF + DBBM, (3) BLOCK-3 made with Solid-PRF fragments + Liquid-PRF + DBBM.

Cell-Membrane-Display Nanotechnology.

Advances in material science have set the stage for nanoparticle-based research with potent applications for the diagnosis, bioimaging, and precise treatment of diseases. Despite the wide range of biomaterials developed, the rational design of biomaterials with predictable bioactivity and safety remains a critical challenge. In recent years, the field of cell-membrane-based therapeutics has emerged as a promising platform for addressing unmet medical needs.