Search Results (1,540)

Background and Objectives: Currently, the development of local drug delivery systems for the treatment of cancer patients is a pressing issue. Such systems allow for the targeted delivery of anticancer drugs directly to the tumor site, ensuring prolonged drug release or reducing the risk of recurrence after tumor removal, minimizing the impact on healthy tissues and thereby reducing the overall toxic load on the body. This work is devoted to evaluating the prospects of using scaffolds based on low-modulus titanium Ti-15Mo alloy with a biomimetic coating as a platform for the local administration of the cytostatic drug cisplatin into the patient’s body. Methods: Porous coatings were obtained by plasma electrolytic oxidation in an aqueous solution of sodium phosphate and calcium acetate with the addition of various components. The influence of coating parameters on the corrosion resistance of samples and on the antiproliferative effect of cisplatin-loaded scaffolds was evaluated. Human K562 hemoblastosis, HT116 intestinal cancer, and SKOV3 ovarian cancer cell lines were used as cell models. Results: It was shown that the addition of sodium phosphate (the PS type electrolyte) provides the formation of a coating with a developed system of interconnected pores characterized by an attractive combination of parameters: high porosity (17%), high pore size (3.9 μm), and considerable thickness (17.4 μm). This coating demonstrated the best corrosion resistance in a Ringer solution as compared to the other tested states. In addition, the PS coating loaded with cisplatin exhibited a pronounced cytotoxic effect on cancer cells. This effect was attributed to its ability to fix cisplatin on the surface, which slows down its release into the extracellular environment, increasing the time of its action, thereby contributing to a more effective (by more than 3 times) suppression of tumor cell proliferation compared to the action of the standard form of the drug in the form of a solution when changing the growth medium and subsequent incubation for 48 h. Conclusions: PS scaffolds made of low-modulus titanium alloy Ti-15Mo with a biomimetic surface in an electrolyte based on an aqueous solution of sodium phosphate and calcium acetate with the addition of sodium silicate can be used as an advanced platform for the local delivery of the cytostatic drug cisplatin, which makes them promising for application in orthopedic oncology. Full article

This review paper presents a comprehensive literature analysis that elucidates the global engagement of research teams in addressing the important problem of finding effective oncology drugs based on the following platinum group metal ions: ruthenium, rhodium and iridium. The necessity to search for new drugs can be attributed, in part, to the predominance of platinum-based chemotherapeutics in clinical practice. However, these drugs face limitations in their clinical application due to their inherent toxicity and the development of resistance by cancer cells. A distinctive attribute of these metal compounds is the formation of diamagnetic stable complexes on +II (Ru) and +III (Rh, Ir) oxidation degrees with a d⁶ electron configuration, a coordination number of six and an octahedral or pseudo-octahedral structure. In this paper we have systematised the findings presented in the literature by classifying the most significant categories of ruthenium, rhodium and iridium compounds, namely piano-stool-type arenes, polypyridine and cyclometalated complexes, dimers and multinuclear complexes. Additionally, the most crucial research challenges connected with metal complexes that have been addressed by scientists have been presented: (i) the application of prodrugs in cancer therapy; (ii) the deployment of complexes as sensitizers in PDT and PACT; (iii) the exploration of complexes as inhibitors of enzymes and biocatalysts; and (iv) the investigation of multiple-target complexes. Furthermore, the objective was to emphasise the accomplishments in this domain in recent years by identifying compounds that have entered the clinical trial phase. Full article

Drug repurposing is the process of discovering new therapeutic indications for already existing drugs. By using already approved molecules with known safety profiles, this approach reduces the time, costs, and failure rates associated with traditional drug development, accelerating the availability of new treatments to patients. Artificial Intelligence (AI) plays a crucial role in drug repurposing by exploiting various computational techniques to analyze and process big datasets of biological and medical information, predict similarities between biomolecules, and identify disease mechanisms. The purpose of this review is to explore the role of AI tools in drug repurposing and underline their applications across various medical domains, mainly in oncology, neurodegenerative disorders, and rare diseases. However, several challenges remain to be addressed. These include the need for a deeper understanding of molecular mechanisms, ethical concerns, regulatory requirements, and issues related to data quality and interpretability. Overall, AI-driven drug repurposing is an innovative and promising field that can transform medical research and drug development, covering unmet medical needs efficiently and cost-effectively. Full article

Background: Minimally invasive hyperthermia and regenerative therapies require materials that deliver precise, localized heat without compromising biocompatibility. Most conventional polymers are thermally insulating and challenging to control in vivo, motivating this review. Objectives: We aimed to (i) examine the use of thermally enhanced biopolymers in hyperthermia-based therapies, (ii) appraise evidence from clinical and preclinical studies, (iii) identify and classify principal applications in regenerative medicine. Methods: A PRISMA-guided systematic review (2020–2025) with predefined inclusion/exclusion criteria was conducted and complemented by a bibliometric analysis using VOSviewer for mapping and visualization. Results: Modifying biopolymers—via functionalization with photothermal or magnetic nanoagents (Au; Fe₂O₃/Fe₃O₄/CoFe₂O₄; CuS; Ag; MXenes, e.g., Nb₂C), crosslinking strategies, and hybrid formulations—significantly increased thermal conductivity, enabling localized hyperthermia and controlled drug release. In vitro and in vivo studies showed that europium-doped iron oxide nanoparticles embedded in chitosan generated heat efficiently while sparing healthy tissues, underscoring the need to balance biocompatibility and thermal performance. Hydrogel systems enriched with carbon nanomaterials (graphene, carbon nanotubes) and matrices such as GelMA, PNIPAM, hyaluronic acid, and PLA/PLGA demonstrated tissue compatibility and effective thermal behavior; graphene was compatible with neural tissue without inducing inflammation. Conclusions: Thermally conductive biopolymers show growing potential for oncology and regenerative medicine. The evidence supports further academic and interdisciplinary research to optimize safety, performance, and translational pathways. Full article

Integrated pharmacokinetic (PK) and pharmacodynamic (PD) models are essential for the understanding of quantitative relationship between drug exposure and response towards the identification of optimal dosing regimens in drug development and clinical therapy. This article summarizes the common PK–PD models being established in oncology, with a focus on combination therapies. Among them, the PK models include those used for practical non-compartmental and compartmental analyses, as well as those for physiologically based modeling that describe and predict exposure to various chemotherapy, targeted therapy, and immunotherapy drugs. Built on proper natural disease progression models, such as the empirical logistic growth curve, the Gompertzian growth model, and their modifications, the integrated PK–PD models recapitulate and predict antitumor drug efficacy, in which the PD models include practical indirect response model and various tumor growth inhibition models, as driven by the mechanistic actions of the drugs administered. Since anticancer drugs are usually co-administered, PK–PD modeling has been extended from monotherapy to combination therapy. However, relying on a single interaction factor or parameter to capitulate complex drug interactions, predict outcomes of different combinations, and determine possible synergism is problematic. Considering the apparent contributions from individual drugs following mutual interactions, a new PK–PD model has been developed for combination therapy, which may be integrated with proper algorism (e.g., the Combination Index method) to critically define combination effects, synergism, additivity, or antagonism. As drug combinations become more complex and individual drug actions are variable, these models should be optimized further to advance the understanding of PK–PD relationships and facilitate the development of improved therapies. Full article

Cancer survivors (CS) constitute an expanding population with underrecognized cardiometabolic risk. Despite substantial improvements in five-year survival rates, both childhood and adult survivors remain at high risk for premature morbidity and mortality. These risks are particularly pronounced following exposure to anthracyclines and/or chest radiotherapy, typically in a dose-dependent manner. In Chile, the establishment of the National Pediatric Antineoplastic Drug Program (PINDA) in 1998 marked a milestone in improving equitable access to high-quality pediatric oncology care through evidence-based treatment protocols across the public health system; the adult counterpart (PANDA) has developed diagnostic, treatment, and monitoring protocols for hematological neoplasms. Few prospective cohort or mechanistic studies have clarified risk stratification or surveillance strategies in survivor populations. The regulated, short-term activation of inflammation and innate immunity can be an adaptive and protective response to tissue injury, whereas persistent low-grade inflammation may trigger neutrophil extracellular traps formation (NETosis) and other maladaptive pathways that accelerate endothelial injury, thrombosis, and adverse cardiovascular remodeling. NETosis represents a putative immunomodulatory target for therapeutic immunomodulation in heart failure and maladaptive left ventricular remodeling in preclinical models. Concurrently, skeletal muscle-derived and hormonal mediators known as exerkines—together with increased NET activity—may modulate the pathophysiology of chronic cardiometabolic disease and contribute to cancer progression, particularly in the context of obesity, diabetes, and insulin resistance. Structured exercise is a promising non-pharmacological intervention that modulates inflammatory and metabolic pathways and may thereby help prevent non-communicable diseases, including cancer. We synthesize basic and clinical evidence to (1) define how cancer therapies promote low-grade inflammation and NETosis; (2) describe how exerkines and structured exercise influence cardiometabolic biology; and (3) evaluate exercise as a mechanistic and clinically pragmatic strategy to reduce long-term CVD risk in pediatric and adult CS. Full article

Drug repurposing, that is, the identification of new therapeutic indications for existing medications, has been shown to be a cost-effective and time-efficient alternative to de novo drug development. This review provides a comprehensive overview of repurposed drugs in veterinary oncology, describing their mechanisms of action, current evidence of clinical benefit, and translational relevance. The therapeutic agents discussed include non-steroidal anti-inflammatory drugs (e.g., piroxicam), metabolic modulators (e.g., metformin), anti-parasitic drugs (e.g., fenbendazole), immunomodulators (e.g., thalidomide, oclacitinib), cardiovascular agents (e.g., propranolol, statins, losartan), and other compounds such as auranofin and disulfiram. A critical evaluation of the extant evidence-based data from preclinical research, naturally occurring tumor models, and clinical studies is provided, with particular emphasis on both the therapeutic potential and the current limitations. The present review also focused on combination strategies and multimodal protocols, where repurposed drugs may enhance the efficacy of chemotherapy, targeted therapies, or immunotherapy. Challenges to clinical implementation, including limited funding, regulatory and ethical considerations, and the need for well-designed, multi-institutional clinical trials, are discussed. Ultimately, drug repurposing represents a practical and translationally valuable approach to broaden therapeutic options, improve quality of life in companion animals, and advance comparative oncology by promoting progress that benefits both veterinary and human patients. Full article

Background: Clinical pharmacy services (CPS) have been shown to confer significant advantages in patient care. It remains to be clarified how CPS resources are allocated across routine care settings. It remains to be clarified which recommendations are made to resolve the drug-related problems (DRP) identified by CPS and which adverse drug reactions (ADR) actually arise from the identified DRP. Methods: Following positive ethical approval, patient chart analyses, evaluation of pharmacy documentation on CPS and pharmacist interviews were performed to characterize CPS at all medical departments of the Bundeswehr Hospital Hamburg. We developed and pre-tested instruments for standardization: A Standard Operating Procedure (SOP) for the practical exercise and documentation of CPS by the pharmacists performing them, a standardized form (checklist) for retrospective data collection as part of this study, and a standardized questionnaire for conducting the pharmacist interviews including a risk assessment according to the NCC-MERP score. Results: In total, 1000 CPS were documented in 504 patients (mean age: 69.95 years; 229 female) on 16,705 treatment days. A total of 66.87% CPS was initiated when pharmacists participated in ward rounds. In all CPS, “Indications” was the topic addressed most frequently (37.70%). “Agents for obstructive respiratory diseases” was the most frequently involved drug class (11.32%). The most frequent processing time per CPS was 16–30 min (48.61%). The number of CPS ranged from 0.36/100 treatment days in dermatology to 12.47 in oncology. Severity of 358 DRP was classified “very severe” (5.03%), “severe” (42.74%), “moderate” (34.36%), “low” (15.08%), “very low” (1.40%), or “without impact” (1.40%). The probability of DRP occurrence was classified as “high” in 13.13% and “very high” in 3.35%. In 15.36% of the DRP, an ADR actually occurred. In 504 patients, 932 specific recommendations were forwarded to solve the DRP identified during CPS. Of those, 53.97% were implemented. Conclusions: In almost all CPS, a considerable number of DRP with serious clinical consequences were identified. Half of the forwarded recommendations were implemented. Full article

Takotsubo syndrome (TTS) is an acute, reversible cardiomyopathy that clinically mimics acute coronary syndrome in the absence of obstructive coronary artery disease. In oncology, TTS may be precipitated by the cancer milieu itself (stress, inflammation, neuroendocrine activation) and by antineoplastic therapies, notably fluoropyrimidines, vascular endothelial growth factor (VEGF) pathway inhibitors, tyrosine kinase inhibitors, and immune checkpoint inhibitors. Cancer currently stands as the second leading cause of morbidity and mortality worldwide. Cancer can directly induce TTS through an increase in catecholamines or indirectly via surgical and chemotherapeutic treatments. Several antineoplastic drugs are associated with an increased risk of TTS. We conducted a narrative, clinically oriented review. This narrative review aims to analyze the pathophysiological link between TTS and cancer and to explore potential preventive and therapeutic strategies in cancer patients. Full article

Cancer is considered today as a prevalent research direction due to the fact that, by 2050, more than 30 million cases will occur, followed by about 19 million deaths. It is expected that scholars will search for new, innovative, and localized therapies to ensure a much more targeted treatment with reduced side effects. Magnetic hydrogels overcome the disadvantages of classical magnetic nanoparticles in various oncological domains, including magnetic hyperthermia, theragnostic, immunotherapy, and, notably, regenerative medicine and contrast substances. We will review the magnetic hydrogel topics that may be involved as a potential application for cancer. Firstly, we present the international context and subject importance in the framework of statistics estimated by some researchers. Then, the magnetic hydrogel synthesis method will be briefly described with examples extracted from the literature. Supplementary, we will emphasize the main attributes of an ideal magnetic hydrogel, and last but not least, we will review some of the latest in vitro and in vivo studies in a direct relationship with magnetic hyperthermia, chemotherapeutic drug release dynamics, and immunotherapy used as single strategies or in combination, by underling the magnetic properties of the hydrogels and importance of application of magnetic fields. We will conclude our review paper by discussing toxicity issues, future trends, limitations, and proposed new approaches to address them. Full article

Background/Objectives: Natural compounds are being increasingly explored as potential adjuvants to conventional drugs in oncological treatments. Regarding breast tumors, several studies indicate that garlic (Allium sativum) may protect against onset, counteracts aggressiveness, and prevents malignant progression of cells from non-invasive tumors. It has been widely demonstrated that garlic derivatives induce apoptosis and reduce invasive potential in ER-positive and triple-negative breast tumor cells. However, the current literature lacks studies investigating their effects on HER2-positive (HER2+) breast cancers. This study therefore aimed to explore the effects of a garlic extract and diallyl disulfide (DADS), one of its most bioactive organosulfur compounds, on HER2+ phenotype breast tumor cells. Methods: The effects of a garlic extract and diallyl disulfide (DADS) were investigated on MDA-MB-453 and SKBR3 breast tumor cell lines. Cell growth, invasive potential, and Akt-related signaling were assessed after 4–72 h of garlic derivatives administration. The intracellular localization of β-catenin was examined with immunofluorescent confocal microscopy. Results: A dual role of DADS, dependent on the duration of treatment, was revealed. Acute administration induced a significant decrease in invasive potential, while prolonged treatment promoted HER2+ cell invasiveness. These effects were directly correlated with the activation of Akt and the nuclear accumulation of β-catenin, known to induce expression of genes associated with tumor malignancy. Conclusions: Although further investigations are needed to establish the exact mechanism and to assess the in vivo reproducibility of these phenomena, our results highlight the heterogeneous response to natural compounds of complex diseases like cancer. Full article

Therapeutic resistance remains a critical barrier in oncology, frequently leading to cancer relapse after initial treatment response. Growing evidence suggests the presence of drug-tolerant persisters (DTPs), a rare subpopulation of cancer cells that survives chemotherapy by entering a reversible specific adaptation. Unlike classical cell resistance, the DTP phenotype is independent of genetic changes and maintained through dynamic regulatory mechanisms. DTPs are phenotypically heterogeneous and can exhibit stem-like and quiescent cell phenotypes, non- or slow proliferation, and remarkable plasticity due to a di-pause-like state and executing epithelial–mesenchymal transition (EMT) or transdifferentiation processes. Despite advances in research, the molecular mechanisms underlying DTPs’ biology and their role in cancer relapse remain only partially understood. The review summarizes the current progress in processes that lead to the acquisition of cellular persistence status, which, in turn, constitute areas of vulnerability that can be exploited in cancer therapy. We highlight anti-DTP therapeutic strategies, including epigenetic modification, cell signaling and transcriptional regulation, metabolic reprogramming, and modification of cell interactions within the tumor microenvironment. Furthermore, we focus on the potential role of nanomaterials in the combat against DTPs. Nanoparticles not only act as part of the drug delivery process, enabling precise DTP targeting and enhancing intracellular drug accumulation, but their intrinsic properties can also be used to eradicate DTPs directly or by enhancing the effectiveness of other therapeutic strategies. The integrated approach offers strong potential to eliminate tumor persistence, prevent recurrence, and improve long-term patient outcomes beyond conventional therapies. Full article

Matrix metalloproteinase-9 (MMP-9) is a zinc-dependent endopeptidase that plays a central role in extracellular matrix (ECM) remodeling, angiogenesis, immune cell trafficking, and cytokine activation. Dysregulated MMP-9 activity has been implicated in the pathogenesis of diverse conditions, including atherosclerosis, aneurysm formation, chronic obstructive pulmonary disease (COPD), asthma, neurodegeneration, and malignancy. Although broad-spectrum synthetic MMP inhibitors were initially developed as therapeutic agents, clinical trials failed due to lack of selectivity, poor tolerability, and impairment with physiological tissue repair. This outcome has shifted attention toward indirect pharmacological modulation of MMP-9 using drugs that are already approved for other indications. In this paper, we review the evidence supporting MMP-9 modulation by established therapeutics and adjunctive strategies. Cardiometabolic agents such as statins, angiotensin-converting enzyme (ACE) inhibitors, angiotensin II receptor blockers (ARBs), metformin, and pioglitazone reduce MMP-9 expression and enzymatic activity, contributing to vascular protection, improved insulin sensitivity, and attenuation of aneurysm progression. Anti-inflammatory and respiratory drugs, including glucocorticoids, phosphodiesterase-4 (PDE4) inhibitors, macrolide antibiotics, montelukast, and nonsteroidal anti-inflammatory drugs (NSAIDs), suppress MMP-9-driven airway inflammation and pathological tissue remodeling in asthma, COPD, and acute lung injury. Tetracycline derivatives, particularly sub-antimicrobial dose doxycycline, directly inhibit MMP-9 activity and are clinically validated in the treatment of periodontal disease and vascular remodeling. Hormone-related therapies such as rapamycin, estradiol, and tamoxifen exert tissue- and disease-specific effects on MMP-9 within endocrine and oncologic pathways. In parallel, nutritional interventions—most notably omega-3 polyunsaturated fatty acids and antioxidant vitamins—provide adjunctive strategies for mitigating MMP-9 activity in chronic inflammatory states. Taken together, these findings position MMP-9 as a modifiable and clinically relevant therapeutic target. The systematic integration of approved pharmacologic agents with lifestyle and nutritional interventions into disease-specific treatment paradigms may facilitate safer, context-specific modulation of MMP-9 activity and unveil novel opportunities for therapeutic repurposing. Full article

Breast cancer remains a leading cause of mortality among women despite advances in early detection and targeted therapies, underscoring the need for safer and more effective treatment options. Drug repurposing offers a promising strategy by leveraging existing pharmacological agents with established safety profiles. Desloratadine, a second-generation H1-histamine receptor antagonist widely prescribed for allergic conditions, has attracted interest in oncology because histamine signaling influences proliferation, angiogenesis, and immune responses, yet its anticancer potential remains poorly understood. In this study, we investigated its effects in MCF-7 breast cancer cells, which harbor wild-type TP53. Desloratadine inhibited cell viability in a dose-dependent manner, with an IC₅₀ of 14.2 µg/mL. Mechanistic analyses revealed that growth inhibition was primarily mediated through apoptosis, confirmed by Hoechst 33342 staining, ROS generation, annexin V/PI staining, and caspase-dependent pathways. Gene expression profiling demonstrated upregulation of TP53, FAS, and BAX, alongside reduced PARP-1 and NF-κB expression, with no detectable STAT3 or BCL2 expression. Flow cytometry indicated accumulation of cells in the sub-G₁ phase and G₂/M arrest, consistent with apoptosis induction. Molecular docking further supported these findings, showing that Desloratadine binds with high affinity to p53 (−7.0 kcal/mol), FAS (−6.8 kcal/mol), and NF-κB (−6.5 kcal/mol), forming stabilizing hydrogen bonds and hydrophobic interactions aligned with the observed gene expression changes. To confirm the functional role of TP53, we generated CRISPR-Cas9 knockout MCF-7 cells. Compared with wild-type cells, these knockout cells displayed markedly reduced sensitivity to Desloratadine, with the IC₅₀ shifting from 14.2 µg/mL to 36.4 µg/mL, demonstrating that p53 is a key mediator of the drug’s cytotoxic effect. Collectively, these findings identify Desloratadine as a potential repurposed drug candidate for breast cancer therapy, acting at least in part through a p53-dependent apoptotic pathway. Full article

Background: Defining specific molecular targets for cancer therapeutics remains a significant challenge in oncology. Many Food and Drug Administration (FDA)-approved anticancer drugs have incomplete target profiles, which limits our understanding of their mechanisms of action and opportunities for drug application. In this context, this study aimed to establish novel, biologically meaningful relationships between anticancer drugs and protein-coding genes. Methods: We developed a pharmacogenomic method that integrates transcriptomic data with drug activity data from the NCI-60 cancer cell line panel to study the interactions between 124 FDA-approved anticancer drugs and 399 cancer-related genes. Through this analysis, we identified gene–drug relationships and created a bipartite interaction network. To evaluate drug similarity, we developed a new index called the B-index. This novel similarity coefficient measures the association between two drugs based on their shared gene targets in the network. The index calculates the intersection of two sets of drug targets while considering the relative proportion of targets exhibited by each drug. For an independent assessment, we compared this network-based similarity with the chemical structural similarity of the drugs, computed based on two structural coefficients: Maximum Common Substructure and Tanimoto. Results: The study identified 1304 statistically significant drug–gene relationships, providing a large-scale network of pharmacogenomic interactions. Clustering analysis of the network, based on the B-index, grouped drugs with common targets together. This grouping was consistent with well-established drug classes and structural characteristics. Well-established drug pairs, such as cytarabine–gemcitabine or afatinib–neratinib, exhibited high B-index and structural similarity values, validating the methodology. Several novel gene associations were discovered, yielding testable hypotheses for mechanism-based repurposing. Conclusions: This work presents a comprehensive, network-based strategy for elucidating cancer drug targets by combining gene expression and drug activity profiles. Additionally, the B-index provides an alternative to conventional chemical similarity metrics, which can facilitate the identification of new therapeutic relationships and inform new drug applications and repositioning. These findings pave the way for the proposal of novel oncology drug targets. Full article