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Methotrexate, a structural analogue of folic acid, is one of the most effective and extensively used drugs for treating many kinds of cancer or severe and resistant forms of autoimmune diseases. In this paper, we take an overview of the present state of knowledge with regards to complex mechanisms of methotrexate action and its applications as immunosuppressive drug or chemotherapeutic agent in oncological combination therapy. In addition, the issue of the potential benefits of methotrexate in the development of neurological disorders in Alzheimer’s disease or myasthenia gravis will be discussed.

A glassy carbon electrode (GCE) was modified with cerium-doped ZnO nanoflowers (Ce-ZnO/GCE) to obtain a sensor for direct simultaneous detection of the cancer drugs epirubicin and methotrexate. XRD, SEM and EDX techniques were used to characterize their morphology and structure. Electrochemical impedance spectroscopy was applied to characterize the electrochemical features of the modified GCE. The experimental conditions were optimized. Diffusion coefficients and heterogeneous rate constants were determined for the oxidation of epirubicin. The differential pulse voltammetric response to epirubicin has a peak near 0.7 V (vs. Ag/AgCl at a scan rate of 50 mV s −1 ) and is linear in the 0.01 to 600 μM concentration range, and the detection limit is 2.3 nM (S/ N  = 5). The differential pulse voltammetric response to methotrexate has a peak near 0.75 V (vs. Ag/AgCl and the same scan rate) and is linear in the 0.01 to 500 μM concentration range, and the detection limit is 6.3 nM (S/ N  = 5). The method was applied to the simultaneous determination of epirubicin and methotrexate in pharmaceutical injections and in spiked diluted blood specimens. Graphical abstract Schematic of an electrochemical sensor based on Ce-doped ZnO nano-flowers modified glassy carbon electrode for detecting epirubicin

Methotrexate (MTX) is a folic acid antagonist used as an effective drug to treat various kinds of cancers. However, MTX has limited use in cancer chemotherapy due to its adverse effects such as poor bioavailability, low specificity, drug resistance, and dose-dependent side effects. To improve lymphatic delivery and reduce toxicity of MTX, MTX-loaded nanoparticles (NPs) were prepared in the present study. NPs were prepared with double emulsion solvent evaporation method using poly(lactide-co-glycolide) (PLGA). NPs were assessed for size, encapsulation efficiency, morphology, Fourier-transform infrared spectroscopy, X-ray diffraction, and thermal characterization. In vitro release profiles and cytotoxicity of these NPs were also evaluated. Prepared NPs and free MTX were administered orally or intravenously (5 mg/kg as MTX) to rats to evaluate their pharmacokinetic characteristics and lymphatic delivery effects. Mean particle size and encapsulation efficiency of NPs were 163.7 ± 10.25 nm and 93.3 ± 0.5%, respectively. Prepared NPs showed a sustained release profile of MTX in vitro and may be effective to cancer cells. Area under the blood concentration-time curve, total clearance, half-life, and lymphatic targeting efficiency were significantly different (p < 0.05) between prepared NPs and free MTX. These results demonstrate that MTX-loaded PLGA NPs are good candidates for targeted delivery of MTX to the lymphatic system.

Carbon nanotubes (CNTs) have the potential to serve as delivery systems for medicinal substances and gene treatments, particularly in cancer treatment. Co-delivery of curcumin (CUR) and Methotrexate (MTX) has shown promise in cancer treatment, as it uses fewer drugs and has fewer side effects. This study used MTX-conjugated albumin (BSA)-based nanoparticles (BSA-MTX) to enhance and assess the efficiency of CUR. In-vitro cytotoxicity tests, DLS, TEM, FTIR, UV/Vis, SEM, and DSC studies assessed the formulations' physical and chemical properties. The Proteinase K enzyme was used to severe amidic linkages between MTX and BSA. The findings demonstrated the efficacy of using ƒ-MWCNT-CUR-BSA-MTX as a vehicle for efficient co-delivery of CUR and MTX in cancer treatment. The MTT colorimetric method was used to evaluate the effect of chemical and medicinal compounds. Cell division was studied using the MTT method to investigate the effect of pure MWCNT, pure CUR, MTX-BSA, and ƒ-MWCNT-CUR-MTX-BSA. Studies on cell lines have shown that the combination of curcumin and MTX with CNT can increase and improve the effectiveness of both drugs against cancer. A combination of drugs curcumin and methotrexate simultaneously had a synergistic effect on MCF-7 cells, which indicated that these drugs could potentially be used as a strategy for both prevention and treatment of breast cancer. Also, ƒ-MWCNT-CUR-MTX-BSA was found to have a significant effect on cancer treatment with minimal toxicity compared to pure curcumin, pure MTX-BSA, MTX, and ƒ-MWCNT alone. Unique properties such as a high ratio of specific surface area to volume, high chemical stability, chemical adsorption ability, high capacity of drug and biomolecules of carbon nanotubes, as well as multiple drug loading at the same time The combination of ƒ-MWCNT-CUR-BSA MTX significantly impacts cancer therapy), are desirable as an alternative option for targeted drug delivery and high therapeutic efficiency.

The effect of chemotherapy for anti-glioblastoma is limited due to insufficient drug delivery across the blood–brain–barrier. Poloxamer 188-coated nanoparticles can enhance the delivery of nanoparticles across the blood–brain–barrier. This study presents the design, preparation, and evaluation of a combination of PLGA nanoparticles (PLGA NPs) loaded with methotrexate (P-MTX NPs) and PLGA nanoparticles loaded with paclitaxel (P-PTX NPs), both of which were surface-modified with poloxamer188. Cranial tumors were induced by implanting C6 cells in a rat model and MRI demonstrated that the tumors were indistinguishable in the two rats with P-MTX NPs + P-PTX NPs treated groups. Brain PET scans exhibited a decreased brain-to-background ratio which could be attributed to the diminished metabolic tumor volume. The expression of Ki-67 as a poor prognosis factor, was significantly lower in P-MTX NPs + P-PTX NPs compared to the control. Furthermore, the biodistribution of PLGA NPs was determined by carbon quantum dots loaded into PLGA NPs (P-CQD NPs), and quantitative analysis of ex-vivo imaging of the dissected organs demonstrated that 17.2 ± 0.6% of the NPs were concentrated in the brain after 48 h. The findings highlight the efficacy of combination nanochemotherapy in glioblastoma treatment, indicating the need for further preclinical studies.

The need for precise modulation of blood concentrations of pharmaceutical molecule, especially for high-risk drugs like Methotrexate (MTX), is underscored by the significant impact of individual variations on treatment efficacy. Achieving selective recognition of pharmaceutical molecules within the complex biological environment is a substantial challenge. To tackle this, we propose a synergistic atomic-molecular docking strategy that utilizes a hybrid-dual single-atom Fe1-Zn1 on a TiO2 photoelectrode to selectively bind to the carboxyl and aminopyrimidine groups of MTX respectively. By integrating this Fe 1 -Zn 1 -TiO 2 photoelectrode with a microcomputer system, an implantable photoelectrochemical-therapeutic drug monitoring (PEC-TDM) system is developed for real-time, continuous in vivo MTX monitoring. This system facilitates personalized therapeutic decision-making and intelligent drug delivery for individualized cancer therapy, potentially revolutionizing oncological care and enhancing patient outcomes. Concentration of methotrexate (MTX) in the blood needs precise monitoring, Here, the authors propose an atomic-molecular docking strategy that utilizes a hybrid-dual single-atom Fe 1 -Zn 1 on TiO 2 photoelectrode to bind to the carboxyl and aminopyrimidine groups of MTX.

This study developed a transdermal drug delivery system for Rheumatoid Arthritis (RA) using a dual-network hydrogel microneedle patch loaded with methotrexate nanocrystals (DHMN@MTX-NCs), and explored its synergistic therapy with Adalimumab (ADA) for a painless, long-acting, and targeted RA treatment. This study synthesized Methacrylated Hyaluronic Acid and Methacrylated Gelatin. MTX-NCs were prepared by solvent-antisolvent precipitation and incorporated into a dual-network hydrogel microneedle patch via centrifugal molding. Evaluations included pharmaceutical properties, mechanical strength, drug release, in vitro anti-inflammatory effects on RAW 264.7 cells, and therapeutic efficacy in a rat RA model. The experimental results show that the prepared MTX-NCs present a spherical shape, an average size of 325.72 nm, a PDI of 0.154, and a drug-loading capacity of 61.3%. The microneedle patch exhibited high puncture efficiency and suitable swelling. In vitro, DHMN@MTX-NCs combined with ADA most strongly inhibited macrophage migration, upregulated IL-10, and downregulated TNF-α, IL-1β, NO, iNOS, and COX-2. In vivo, both monotherapy and combination therapy reduced joint swelling, bone erosion, and histopathological damage. Ultimately, the study demonstrated the synergistic anti-inflammatory efficacy of DHMN@MTX-NCs combined with ADA, providing a novel, non-invasive, and targeted therapeutic strategy for RA.

The nonspecific nature of cancer drug delivery often results in substantial toxic side effects during treatments for breast cancer. To mitigate these negative outcomes, our approach involves loading methotrexate (MTX) within carbon quantum dots (CQDs) synthesized from folic acid, which are then enveloped in exosomal membranes obtained from breast cancer cells (Ex@MTX-CQDs). Analysis utilizing nanoparticle tracking techniques has demonstrated that these Ex@MTX-CQDs maintain the physical and biochemical properties of their exosomal precursors. The release profile of MTX indicated a restricted release percentage (less than 10%) under normal physiological conditions, which is contrasted by a more consistent release rate (approximately 65%) when emulating the conditions found within tumor tissues. The toxicological assessments have confirmed that the presence of exosomes combined with leftover folic acid significantly improves the delivery efficacy of MTX directly to the cancerous cells through the binding to folate and heparan sulfate proteoglycan receptors. This process results in increased disruption of the mitochondrial membrane potential and subsequently triggers apoptosis, ultimately leading to the destruction of cancerous cells. Our research could potentially contribute to the further innovation and application of nanocarriers derived from biological sources for the targeted treatment of breast cancer.

The simultaneous administration of multiple drugs within identical nanocarriers to cancer cells or tissues can result in the effective action of drugs at reduced concentrations. In this investigation, PAMAM dendrimers (G4-PAMAM) were employed to link with methotrexate (MTX) using DCC/NHS chemistry and followed by the entrapment of curcumin (Cur) within it. The establishment of covalent bonds between MTX and the PAMAM dendrimer led to PAMAM-MTX interaction, verified and described through FT-IR. Various techniques were employed to evaluate the structural properties of the prepared Cur-PAMAM-MTX NC. The Cur-PAMAM-MTX NC, after preparation, exhibited a particle size of 249 nm, with an encapsulation efficiency (EE) of ~ 81% for Cur. The cumulative in vitro release of Cur-loaded NC indicated a controlled release influenced by time and pH. The cell study results revealed that Cur-PAMAM-MTX NC exhibited significantly higher cytotoxicity than free MTX, Cur, and other formulations tested in vitro. The synergistic effect of co-delivery of MTX and Cur by PAMAM significantly increased cytotoxicity. Besides, the significant ROS level rising has been shown in the treated cells with MTX-PAMAM-Cur. Considering these findings, the co-delivery NC shows promise for additional in vitro investigations and possesses the capacity to function as an effective framework for the combined delivery of MTX and Cur in cervical cancer chemotherapy.

Methotrexate (MTX) is widely used for rheumatoid arthritis (RA) but has poor targeting and significant side effects. This study developed MTX-loaded lipid nanoparticles modified with PVCAM-1 peptide (MTX@LNP-PVCAM-1) to enhance targeting and reduce toxicity. MTX@LNP-PVCAM-1 was prepared using the thin-film dispersion method. Particle size and morphology were assessed by dynamic light scattering (DLS) and transmission electron microscopy (TEM). Biocompatibility was tested using human umbilical vein endothelial cells (HUVEC) and hemolysis assays. Cellular uptake was examined via fluorescence microscopy, while cytotoxicity and cell migration inhibition were evaluated using CCK-8 and scratch assays. Inflammatory cytokines (IL-1β, IL-6) were measured by ELISA. Distribution in adjuvant-induced arthritis (AIA) rats was observed using in vivo imaging, and safety and anti-inflammatory effects were assessed through blood tests, paw volume, joint scores, and histology. MTX@LNP-PVCAM-1 had an average particle size of 168.5 nm, PDI of 0.142, and zeta potential of -12.1 mV, with spherical morphology. It exhibited pH responsiveness and good biocompatibility. Compared with unmodified MTX@LNP, PVCAM-1 surface modification significantly increased cellular uptake efficiency ( <0.05) and more effectively inhibited the growth ( <0.05), migration ( <0.05), and secretion of inflammatory cytokines (significantly reduced levels of IL-1β and IL-6, <0.05) of synovial fibroblasts. In animal experiments, the accumulation of MTX@LNP-PVCAM-1 in inflamed sites was significantly higher than that of MTX@LNP ( <0.05), demonstrating good targeting. Moreover, it enhanced the anti-inflammatory effects of methotrexate in AIA rats, significantly reducing paw swelling ( <0.05) and joint clinical scores ( <0.05). Importantly, it had no significant effect on the blood routine indicators of rats ( >0.05), indicating no obvious toxicity. MTX@LNP-PVCAM-1 combines passive and active targeting, delivering MTX efficiently to inflamed sites and reducing toxicity. This approach enhances anti-inflammatory effects in AIA rats, offering a potential strategy for low-toxicity RA treatment.