Targets

Resveratrol, a naturally occurring polyphenol found in grapes, berries, and peanuts, has garnered significant attention for its potential anti-cancer properties. This review provides a comprehensive analysis of its role in cancer therapy, both as a standalone treatment and in combination with other therapeutic approaches. This review explores the molecular mechanisms underlying resveratrol’s anti-cancer effects, including its antioxidant activity, modulation of cellular signaling pathways, antiproliferative properties, anti-inflammatory effects, and epigenetic influences. This review also examines in vitro and in vivo studies that highlight resveratrol’s efficacy against various cancer types. Furthermore, the synergistic effects of resveratrol when used in conjunction with conventional treatments like chemotherapy and radiotherapy, as well as targeted therapies and immunotherapies, are discussed. Despite promising preclinical results, this review addresses the challenges and limitations faced in translating these findings into clinical practice, including issues of bioavailability and toxicity. Finally, it outlines future research directions and the potential for resveratrol to enhance existing cancer treatment regimens. This review aims to provide a thorough understanding of resveratrol’s therapeutic potential and to identify areas for further investigation in the quest for effective cancer treatments. Full article

Immunological risk factors in recurrent pregnancy loss include autoantibodies, alterations in NK cell number and function, regulatory T cells, the human leukocyte antigen system (HLA), etc., where the treatment options aim to regulate immune dysfunction. Intralipid is a synthetic product traditionally used as a dietary supplement consisting of soybean oil combined with refined egg phospholipids. It has been shown that intralipid exerts physiologic activities, including altering immunological functions, that may benefit patients with certain types of infertility. In this review, we summarize the current state of the art of targeting NK cells and NK cell activity in women with implantation failure or/and recurrent pregnancy loss. We focus on intralipid mechanisms of action and outcomes of clinical trials regarding the efficacy and safety of intralipid infusions in women with reproductive failure. More studies are needed to reveal all the aspects of the safety and effectiveness of intralipid administration in reproductive failure treatment. Full article

Glucocorticoids are the mainstay treatments for diverse pathologies. Ultraviolet (UV) radiation is a risk factor for alterations in the skin, including cell viability (skin thickness), mediators of angiogenesis (blood flow/inflammation), and remodeling of the extracellular matrix (skin integrity). We examined the effects of hydrocortisone on cell viability, p53 promoter activity, and expression of interleukin-8 (IL-8), matrixmetalloproteinase-1 (MMP-1), and tissue inhibitor of matrixmetalloproteinase-1 (TIMP-1) in non-irradiated, UVA-radiated, and UVB-irradiated dermal fibroblasts and melanoma cells. Hydrocortisone inhibited cell viability by stimulating p53 promoter activity in fibroblasts, but not in melanoma cells, which instead showed a decrease in p53 promoter activity in non-irradiated and UVA-irradiated cells. Hydrocortisone inhibited the IL-8 protein levels in non-irradiated and UV-irradiated fibroblasts, and in the non-irradiated melanoma cells, by post-transcriptional mechanisms. Hydrocortisone increased the MMP-1 to TIMP-1 ratio in non-irradiated and UVB-irradiated fibroblasts by inhibiting TIMP-1, and in melanoma cells by inhibiting TIMP-1 in non-irradiated cells and stimulating MMP-1 in UV-irradiated cells. It may be inferred that hydrocortisone has the potential to cause skin thinning by inhibiting cell viability, angiogenesis, and deposition of structural ECM by fibroblasts, regardless of UV exposure, and facilitating UV-exposed melanoma cells by increasing MMP-1 expression. Full article

Drug resistance in cancer is a significant contributor to high mortality, and it exists in the complex form of a multi-parameter. Here, we unravel the roles of tumor heterogeneity, intratumoral physiological barriers, and safe havens in the onset and progression of cancer drug resistance, and outline strategies for resolution. We advocate for a “three-step approach” to reverse cancer drug resistance, including the management of cancer evolution and early intervention, the normalization of intratumoral physiological barriers, and the breakage of tumor safe havens. This approach aims to effectively manage the source of drug resistance, dismantle the breeding grounds of drug resistance, and break the sanctuaries where drug resistance hides. Full article

The vast majority of advanced NSCLC cases are histologically represented by adenocarcinomas. EGFR activating mutations (exon 19 deletions, exon 21 L858R substitutions, exon 20 insertions) represent one of the most common druggable alterations. Since erlotinib’s FDA approval in 2013, EGFR-TKIs have represented a staple of EGFR+ advanced NSCLC treatment, with osimertinib representing the latest major FDA-approved third-generation EGFR-TKI. In recent years, however, several preclinical data have highlighted promising results regarding combination therapies involving EGFR-TKIs plus chemotherapy, and various recent clinical trials have confirmed these results. In addition, in 2021, amivantamab was the first FDA-approved mAb for the treatment of EGFR+ advanced NSCLC patients; according to some extremely up-to-date clinical trials, the combination of amivantamab plus chemotherapy is also associated with superior results. Therefore, this paper aims to provide a comprehensive review of both the bases and the latest evidence of the combination therapies involving EGFR+ advanced NSCLC patients. Full article

Epigenetic modulation of DNA and histones facilitated by and histone deacetylases (HDAC) is associated with the development and progression of many cancers, although less is known about DNA methyltransferase (DNMT) in oral cancers and the regulation of these targets. Using commercially available cell lines, oral squamous cell carcinomas (SCC4, SCC9, SCC15, SCC25, and CAL27), and normal gingival fibroblasts (HGF-1), growth assays and mRNA expression were evaluated using ANOVA. These results revealed homeostasis enzyme DNMT1 expression was significantly higher among slow-growing HGF-1 cells than among fast-growing oral cancers, p < 0.05. In contrast, DNMT3A and DNMT3B expression was significantly higher among oral cancers compared with HGF-1 cells, p < 0.05. However, differential expression of HDAC1 and HDAC2 was observed among SCC4, SCC25, and CAL27 cells. Further analysis of miR-152 (regulation and control of DNMT expression) and miR-21, miR-221, and miR-145 (regulation of HDAC expression) revealed all oral cancers produced miR-21, but none produced miR-221. However, differential expression of miR-145 (SCC15) and miR-152 (SCC25) suggested alternative epigenetic pathways and mechanisms of DNMT and HDAC regulation may be responsible for some of the observations revealed in this study. Full article

The significance of hydrogen sulfide (H₂S) in biological research is covered in detail in this work. H₂S is a crucial gas-signaling molecule that is involved in a wide range of illnesses and biological processes. Whether H₂S has a beneficial therapeutic effect or negative pathological toxicity in an organism depends on changes in its concentration. A novel approach to treatment is the regulation of H₂S production by medications or other measures. Furthermore, H₂S is a useful marker for disease assessment because of its dual nature and sensitivity. We can better understand the onset and progression of disease by developing probes to track changes in H₂S concentration based on the nucleophilicity, reducing properties, and metal coordination properties of H₂S. This will aid in diagnosis and treatment. These results demonstrate the enormous potential of H₂S in the detection and management of disease. Future studies should concentrate on clarifying the relationship between diseases and the mechanism of action of H₂S in organisms. Ultimately, this work opens new possibilities for disease diagnosis and treatment while highlighting the significance of H₂S in biological research. Future clinical practice and medical advancements will benefit greatly from our thorough understanding of the mechanism of action and therapeutic applications of H₂S. Full article

The landscape of cancer therapy has gained major impetus through the development of materials capable of selectively targeting cancer cells while sparing normal cells. Synthetic peptides are appealing as scaffolds for the creation of such materials. They are small in size, amenable to chemical synthesis and functionalization, and possess diverse chemical and structural space for modulating targeting properties. Here, we review some fundamental insights into the design, discovery, and evolution of peptide-based targeting agents, with a particular focus on two types of cancer cell targets: unique/overexpressed surface receptors and abnormal physiological properties. We highlight the cutting-edge strategies from the literature of the last two decades that demonstrate innovative approaches to constructing receptor-specific cyclic binders and stimulus-responsive targeting materials. Additionally, we discuss potential future directions for advancing this field, with the aim of pushing the frontiers of targeted cancer therapy forward. Full article

Facing the increasingly global crisis of antibiotic resistance, it is urgent to develop new antibacterial agents and methods. Simultaneously, as research progresses, the occurrence, development, and treatment of diseases, especially some malignant cancers, are found to be closely associated with the bacterial microenvironment, prompting us to reconsider the efficiency of existing antibacterial strategies for disease treatments. Bacteriophages have been employed as antibacterial agents for an extended period owing to their high biocompatibility and particular targetability toward the host bacterial strains. Nonetheless, they are almost neglected due to their slow and limited efficacy in antibacterial practice, especially in acute and severe infectious cases. In recent years, fantastic advancements in various biochemical technologies, such as bacteriophage display technology, genetic engineering, and chemical molecular engineering, have enabled scientists to conduct a broader range of modifications and transformations on the existing bacteriophages with inherited unique characteristics of themselves. As a result, a series of novel bacteriophage platforms are designed and fabricated with significantly enhanced properties and multiplied functionalities. These offer new avenues for combating infections caused by drug-resistant bacteria and treatment of malignancies that are associated with bacterial infections, holding great significance and potential in the innovative theranostic applications. Full article

Cancer remains a significant global health challenge despite advancements in diagnosis and treatment. Traditional cancer therapies often face limitations such as toxicity and drug resistance. Drug repurposing has emerged as a promising strategy to overcome these challenges by identifying new therapeutic uses for existing drugs. This review explores the potential of repurposing positive inotropic agents, which are traditionally used in cardiovascular medicine, for cancer therapy. Positive inotropic agents, including cardiac glycosides, β-agonists, phosphodiesterase inhibitors, and calcium sensitizers have shown preclinical evidence of anti-tumor activity through various mechanisms, such as modulation of the intracellular signaling pathways, increasing cyclic adenosine monophosphate (cAMP) levels, the production of nitric oxide, and decreasing reactive oxygen species levels. Despite the absence of specific clinical trials in this area, these findings suggest a promising avenue for further research and development of combination therapies to improve cancer treatment outcomes. However, challenges such as elucidating specific anti-tumor mechanisms, identifying predictive biomarkers, and optimizing safety profiles need to be addressed to fully realize the therapeutic potential of positive inotropic agents in oncology. Full article

The interactions between carbon dots (C-dots) and cells and the corresponding subcellular organelle localization are both significant for bio-sensing and bio-imaging. In this study, we explore cellular uptake and internalization behaviors of two kinds of lipophilic unit-emitting C-dots for three different kinds of cells. It is found that both C-dots can localize in lipid droplets with high efficiency. Compared with commercial dyes, the imaged lipid droplets by the proposed C-dots possess well-defined outlines. Based on such superior imaging performances, the quantification of lipid droplets for cells pretreated by oleic acid stimulation and starvation is well achieved. Full article

Fibrosarcoma represents a significant challenge in oncology, characterized by high invasiveness and a poor prognosis. Gelatinases, particularly matrix metalloproteinases MMP-2 and MMP-9, play a pivotal role in the degradation of the extracellular matrix, facilitating tumor invasion and metastasis. Inhibiting these enzymes has emerged as a promising therapeutic strategy. This review evaluates the progress in the development and therapeutic potential of gelatinase inhibitors as treatments for fibrosarcoma over the last decade, highlighting molecular mechanisms and future directions. A comprehensive literature review was conducted, focusing on studies published from 2013 to 2023. Research articles and review papers relevant to gelatinase inhibition and fibrosarcoma were examined to assess the efficacy and mechanisms of gelatinase inhibitors. Gelatinase inhibitors have shown the potential to reduce tumor progression, invasion, and metastasis in fibrosarcoma. Clinical trials, although limited, have indicated that these inhibitors can be effectively integrated into existing therapeutic regimens, offering a reduction in metastatic spread and potentially improving patient survival rates. Mechanistic studies suggest that the inhibition of MMP-2 and MMP-9 disrupts critical pathways involved in tumor growth and cell invasion. Gelatinase inhibition represents a viable and promising approach to fibrosarcoma treatment. Future research should focus on developing more specific inhibitors, understanding long-term outcomes, and integrating gelatinase inhibition into multimodal treatment strategies to enhance efficacy. Full article

This study aimed to investigate whether non-fasting plasma triglycerides were associated with diabetes mortality. It included 7312 US adult participants. Diabetes mortality data were obtained via the linkage to National Death Index (NDI) records. Hazard ratios of non-fasting plasma triglycerides for diabetes mortality were assessed using Cox proportional hazards models, adjusting for age, gender, ethnicity, obesity, poverty–income ratio, education levels, physical activity, alcohol consumption, cigarette smoking status, survey period, hypercholesterolemia, hypertension, diabetes, and family history of diabetes. Among these participants, 1180 had diabetes. A total of 420 diabetes-caused deaths were recorded during a mean follow-up of 16.8 years. A 1-natural-log-unit increase in non-fasting plasma triglycerides was associated with a 41% higher diabetes mortality risk (hazard ratio, 1.41; 95% confidence interval, 1.19–1.67). Participants with non-fasting plasma triglycerides in the highest quintile, versus those in the lowest quintile, had a 141% higher diabetes mortality risk (hazard ratio, 2.41; 95% confidence interval, 1.46–3.97). The positive association of non-fasting plasma triglycerides with diabetes mortality was independent of diabetes status at the baseline. In conclusion, this study demonstrated that non-fasting plasma triglycerides were positively associated with diabetes mortality, independent of diabetes status at baseline. Non-fasting triglycerides may be a therapeutic target for diabetes-related complications. Full article

Background: Staphylococcus aureus is a leading cause of skin and bloodstream infections in humans. Antibiotic resistant strains of S. aureus continue to be a problem in treating patients that are infected, so treatment options are needed. A drug discovery project identified SK-03-92 as a novel anti-staphylococcal drug, but the SK-03-92 mechanism of action is unknown. We hypothesized that a lethal factor was being released by the bacteria that killed siblings. Methods: In this study, filtration through molecular weight cut-off filters as well as boiling, trypsin treatment, and proteinase K treatment were used to ascertain what the lethal factor was released by SK-03-92 treated S. aureus cells. Results: Filtration through molecular weight cut-off filters demonstrated the lethal factor released by SK-03-92 treated S. aureus cells had a molecular cut-off between 10,000 Da and 30,000 Da that killed fresh S. aureus cells but was not released by untreated cells. Through proteinase K digestion, trypsin digestion, and boiling experiments, the lethal factor was shown to be a protein. Further experiments are needed to identify what proteins released following SK-03-92 treatment cause the death of S. aureus cells. Conclusions: The data show that SK-03-92 treatment causes S. aureus to release a lethal factor protein that kills S. aureus cells, suggesting a new mechanism of action for an antibacterial drug. Full article

Honey has become popular as a potential treatment for several ailments, including cancer. Honeys from different parts of the world have been shown to have different anti-proliferative, immune-modulatory, and anti-inflammatory actions. Yemeni Sidr honey (YSH) is world-renowned for its anti-inflammatory activity and has been suggested to have anti-cancer activity, although empirical evidence is lacking. We tested three YSH samples by HPLC to show they contained similar sugars and an overlapping group of phenolic and flavonoid components, as described previously. YSH’s apoptotic and anti-proliferative activities were measured in in vitro models of cancer growth. The treatment of breast cancer cell lines (MDA-MB-231 and MCF-7), a cervical cancer cell line (HeLa), and mouse melanoma cells (B16-BL6) with 1% (w/v) YSH in media for 48–72 h almost completely inhibited cell proliferation and promoted cell apoptosis. In contrast, a non-malignant HBL-100 cell line was more resistant to treatment with YSH. This suggests that YSH may be a good candidate as an anti-cancer treatment, which requires further study. Full article

Hepatocellular carcinoma is a pressing global health issue, ranking as the third leading cause of cancer-related mortality in humans. Chronic liver diseases, such as hepatitis B and C infections and cirrhosis, are often associated with hepatocellular carcinoma, necessitating ongoing research for improved diagnostic and therapeutic strategies. Animal models, including both spontaneous and chemically induced models like diethylnitrosamine, play a pivotal role in understanding hepatocellular carcinoma mechanisms. Metabolic alterations in tumoral hepatocytes contribute significantly to cancer initiation and progression, impacting energy metabolism and cell survival. Lectins, specifically Concanavalin A, provide valuable insights into altered glycosylation patterns in cancer cells. This study employs lectin histochemistry to assess hepatic alterations in Concanavalin A expression in a murine model of diethylnitrosamine-induced hepatocellular carcinoma. Utilizing confocal laser scanning microscopy, our study unveils notable changes in Concanavalin A subcellular localization and intensity distribution in hepatocellular carcinoma compared with healthy liver tissue. A significant increase in the Concanavalin A labeling within the tumoral cells and a shifting of the expression within the perinuclear space is observed. These findings offer valuable insights into molecular changes in hepatocellular carcinoma, providing potential avenues for diagnostic and therapeutic advancements. Full article

Phycobiliproteins (PBPs) are accessory light-harvesting pigment complexes found in cyanobacteria, red algae, and certain types of cryptophytes. The unique spectral features (strong absorbance and fluorescence), proteinaceous nature, and some imperative properties such as the anti-oxidative, hepato-protective, anti-inflammatory, and anti-aging activity of PBPs allow their use in biomedical industries. However, basic research and technological innovations are required to explore their potential in biomedical applications. The techniques responsible for therapeutic effects need to be standardized for medical application purposes. This review focuses on the current status of PBPs, their structure, functions, methods of preparation, and applications. Additionally, the stability, bioavailability, and safety issues of PBPs, along with their use in therapeutics, are discussed. Full article

Cell-surface glycans are abundant and complex and play a critical role in maintaining protein stability, regulating cell behavior, and participating in cell communication. Obtaining structural information on glycans in situ is helpful to further understand the role of glycans in the physiological and pathological processes of cells and the regulatory mechanism. To achieve this, we can use recognition or labeling strategies to convert the presence of glycans on the cell surface into signals that can be detected. Currently, many different types of in situ sensing strategies for glycans have been developed. The spatial control of the conversion process can realize the restriction of glycan detection to specific proteins, and the introduction of signal amplification technology into the conversion process can improve the sensitivity of sensing. In this paper, the recent progress of glycan labeling methods and sensing technology is reviewed, and the future development direction is prospected. Full article

The sensitive and effective detection of microRNAs (miRNAs) is of great significance since miRNAs have been proven to have undeniable importance in participating in many biological processes. Herein, we present a novel, sensitive, label-free electrochemical miRNA detection method. Three signal amplification techniques are incorporated in this method, including the efficient conjugate of primer-modified polystyrene spheres (PS) with magnetic beads (MBs) triggered by target miRNA, template-free surface-initiated enzymatic polymerization (SIEP) on the primers, and the use of copper ions in square wave voltammetry (SWV) for detecting acidically depurinated primers. Cooperating with the electrochemical approach, this method was able to achieve a detection limit of 120 aM. With an attomole level of sensitivity and easiness of manipulation, this novel method is suitable for miRNA routine detection in both research and clinical aspects. Full article