Search Results (105)

Background/Objectives: Cisplatin remains a cornerstone chemotherapeutic agent for non-small-cell lung cancer (NSCLC) treatment, yet its clinical utility is substantially limited by acquired resistance and the inadequate suppression of tumor metastasis. Emerging evidence implicates interleukin 6 (IL-6) as a critical mediator of chemoresistance through cancer stem cell (CSC) enrichment and metastasis promotion via epithelial–mesenchymal transition (EMT) induction, ultimately contributing to cisplatin therapy failure. This study sought to address these challenges by designing a nanoplatform with two innovative aims: (1) to achieve active tumor targeting through binding to the IL-6 receptor (IL-6R), and (2) to concurrently inhibit IL-6-mediated chemoresistance signaling pathways. Methods: A lipid–polymer hybrid nanoparticle (LPC) encapsulating cisplatin was synthesized and subsequently surface-functionalized with tocilizumab (TCZ), a monoclonal antibody that targets IL-6R. The therapeutic efficacy of this TCZ-modified nanoparticle (LPC-TCZ) was assessed through a series of in vitro and in vivo experiments, focusing on the inhibition of EMT, expression of CSC markers, tumor growth, and metastasis. Results: Systematic in vitro and in vivo evaluations revealed that LPC-TCZ synergistically attenuated both EMT progression and CSC marker expression through the targeted blockade of IL-6/STAT3 signaling. This multimodal therapeutic strategy demonstrated superior tumor growth inhibition and metastatic suppression compared to conventional cisplatin monotherapy. Conclusions: Our findings establish a nanotechnology-enabled approach to potentiate cisplatin efficacy by simultaneously countering chemoresistance mechanisms and metastatic pathways in NSCLC management. Full article

Glioblastoma is the most common and aggressive malignant primary brain tumour. Patients with glioblastoma have a median survival of only around 14.6 months after diagnosis, despite the availability of various conventional multimodal treatments including chemotherapy, radiation therapy, and surgery. Therefore, photodynamic therapy (PDT) has emerged as an advanced, selective and more controlled therapeutic approach, which has minimal systemic toxicity and fewer side effects. PDT is a less invasive therapy that targets all cells or tissues that possess the photosensitizer (PS) itself, without affecting the surrounding healthy tissues. Polymeric NPs (PNPs) as carriers can improve the targeting ability and stability of PSs and co-deliver various anticancer agents to achieve combined cancer therapy. Because of their versatile tuneable features, these PNPs have the capacity to open tight junctions of the blood–brain barrier (BBB), easily transport drugs across the BBB, protect against enzymatic degradation, prolong the systemic circulation, and sustainably release the drug. Conjugated polymer NPs, poly(lactic-co-glycolic acid)-based NPs, lipid–polymer hybrid NPs, and polyethylene-glycolated PNPs have demonstrated great potential in PDT owing to their unique biocompatibility and optical properties. Although the combination of PDT and PNPs has great potential and can provide several benefits over conventional cancer therapies, there are several limitations that are hindering its translation into clinical use. This review aims to summarize the recent advances in the combined use of PNPs and PDT in the case of glioblastoma treatment. By evaluating various types of PDT and PNPs, this review emphasizes how these innovative approaches can play an important role in overcoming glioblastoma-associated critical challenges, including BBB and tumour heterogeneity. Furthermore, this review also discusses the challenges and future directions for PNPs and PDT, which provides insight into the potential solutions to various problems that are hindering their clinical translation in glioblastoma treatment. Full article

The efficient oral delivery of therapeutic proteins and peptides poses a tremendous challenge due to their inherent instability, large molecular size, and susceptibility to enzymatic degradation. Several nanocarrier systems, such as liposomes, solid lipid nanoparticles, and polymeric nanoparticles, have been explored to overcome these problems. Liposomes and other lipid-based nanocarriers show excellent biocompatibility and the ability to encapsulate hydrophobic and hydrophilic drugs; however, they often suffer from poor structural stability, premature leakage of the loaded drugs, and poor encapsulation efficiency for macromolecular peptides and proteins. On the other hand, polymeric nanoparticles are more stable and allow better control over drug release; nevertheless, they usually lack the necessary biocompatibility and cellular uptake efficiency. Recently, lipid-polymer hybrid nanoparticles (LPHNs) have emerged as an advanced solution combining the structural stability of polymers and the biocompatibility and surface functionalities of lipids to enhance the controlled release, stability, and bioavailability of protein and peptide drugs. In this review, an attempt was made to set a clear definition of the LPHNs and extend the concept and area, so to our knowledge, this is the first review that highlights six categories of the LPHNs based on their anatomy. Moreover, this review offers a detailed analysis of LPHN preparation methods, including conventional and nonconventional one-step and two-step processes, nanoprecipitation, microfluidic mixing, and emulsification methods. Moreover, the material attributes and critical process parameters affecting the output of the preparation methods were illustrated with supporting examples to enable researchers to select the suitable preparation method, excipients, and parameters to be manipulated to get the LPHNs with the predetermined quality. The number of reviews focusing on the formulation of peptide/protein pharmaceutics usually focus on a specific drug like insulin. To our knowledge, this is the first review that generally discusses LPHN-based delivery of biopharmaceuticals. by discussing representative examples of previous reports comparing them to a variety of nanocarrier systems to show the potentiality of the LPHNs to deliver peptides and proteins. Moreover, some ideas and suggestions were proposed by the authors to tackle some of the shortcomings highlighted in these studies. By presenting this comprehensive overview of LPHN preparation strategies and critically analyzing literature studies on this topic and pointing out their strong and weak points, this review has shown the gaps and enlightened avenues for future research. Full article

Background/Objectives: This research focuses on the development and optimization of polymer–lipid hybrid nanoparticles (PLHNs) using two grades of mPEG-PCL co-polymers in combination with DPPC and lecithin to address the biopharmaceutical challenges of acalabrutinib (ACP), a selective treatment for different hematological malignancies. Methods: Variations in the mPEG-to-ε-caprolactone ratio influenced both the molecular weight (Mw) of the synthesized co-polymers and their aqueous phase affinity. The ACP-loaded PLHNs (ACP-PLHNs) were optimized using a circumscribed central composite design. The in vivo studies were performed in Wistar rats. Results: The lipophilic mPEG-PCL (Mw = 9817.67 Da) resulted in PLHNs with a particle size of 155.91 nm and 40.08% drug loading, while the hydrophilic mPEG-PCL (Mw = 23,615.84 Da) yielded PLHNs with a relatively larger size (223.46 nm) and relatively higher drug loading (46.59%). The drug release profiles were polymer-grade dependent: lipophilic ACP-PLHNs (lACP-PLHNs) sustained release up to 30 h in pH 7.2 buffer, while hydrophilic ACP-PLHNs (hACP-PLHNs) completed release within 24 h. Stability studies showed greater stability for lACP-PLHNs, likely due to reduced molecular rearrangement from the chemically stable lipophilic co-polymer. Conclusions: Oral administration of both formulations exhibited a 2-fold (p < 0.001) improvement in the C_max and AUC_0-tlast and a 3.9-fold (p < 0.001) increase in the relatively oral bioavailability compared to the conventional ACP suspension in male wistar rats. Full article

We developed a novel biodegradable poly(lactic-co-glycolic acid) (PLGA) polymer chemically modified with paclitaxel (PTX) to form a PLGA-PTX hybrid. Pre-modification of PTX enhanced its loading in PLGA-PTX nanoparticles (NPs). Background/Objectives: PTX is one of the most effective chemotherapy agents used in cancer therapy. The primary mode of PTX’s action is the hyperstabilization of microtubules leading to cell growth arrest. Although highly potent, the drug is water insoluble and requires the Cremophor EL excipient. The toxic effects of the free drug (e.g., neurotoxicity) as well as its solubilizing agent are well established. Thus, there is strong clinical rationale and need for exploring alternative PTX delivery approaches, retaining biological activity and minimizing systemic effects. Methods: The PTX modification method features reacting the C-2′ and C-7 residues with a linker (succinic anhydride) to produce easily accessible carboxyl groups on the PTX for enhanced coupling to the hydroxyl group of PLGA. The PLGA-PTX hybrid, formed via esterification reaction, was used to formulate lipid-coated PLGA-PTX NPs. As proof of concept, the PLGA-PTX NPs were tested in ovarian cancer (OvCA) models, including several patient-derived cell lines (PDCLs), one of which was generated from a platinum-resistant patient. Results: The PLGA-PTX NPs critically remained stable in water and serum while enabling slow drug release. Importantly, PLGA-PTX NPs demonstrated biological activity. Conclusions: We suggest that this approach offers both a new and effective PTX formulation and a possible path towards the development of a new generation of OvCA treatment. Full article

Theranostic nanoparticles integrate diagnostic and therapeutic potential, representing a promising approach in precision medicine. Accordingly, numerous inventions have been patented to protect novel formulations and methods. This review examines the evolution of patented theranostic nanoparticles, focusing on organic nanosystems, particularly polymeric and lipid nanoparticles, to assess their development, technological advances, and patentability. A scoping review approach was conducted following the Preferred Reporting Items for Systematic reviews and Meta-Analyses (PRISMA) guidelines in the World Intellectual Property Organization (WIPO) and European Patent Office (EPO) database. The search included patents filed within the last ten years (2014–2024) that specifically claimed organic and/or hybrid theranostic nanoparticles. Data extraction focused on nanoparticle composition, synthesis methods, functionalization strategies, and theranostic applications. The search identified 130 patents, of which 13 met the inclusion criteria. These patents were primarily filed by inventors from the United States, Canada, Great Britain, Italy, and China. Polymeric nanoparticles were frequently engineered for targeted drug delivery and imaging, utilizing hyperbranched polyesters, sulfated polymers, or chitosan-based formulations. Lipid nanoparticles were often hybridized with inorganic nanomaterials or magnetic nanostructures to enhance their theranostic potential. While most patents detailed synthesis methods and physicochemical characterizations, only a few provided comprehensive preclinical validation, limiting their demonstrated efficacy. The analysis of recent patents highlights significant advances in the design and application of theranostic nanoparticles. However, a notable gap remains in validating these nanosystems for clinical translation. Future efforts should emphasize robust preclinical data, including in vitro and in vivo assessments, to enhance patent quality and applicability to substantiate the claimed theranostic capabilities. Full article

Background: Lipid nanoparticles (LNPs) and polyethyleneimine (PEI) have independently been used for DNA complexation and delivery. However, non-ideal gene delivery efficiency and toxicity have hindered their clinical translation. We developed DNA-PEI-LNPs as a strategy to overcome these limitations and enhance DNA delivery and transgene expression. Methods: Three microfluidic mixing protocols were evaluated: (i) LNPs without PEI, (ii) a single-step process incorporating PEI in the organic phase, and (iii) a two-step process with DNA pre-complexed with PEI before LNP incorporation. The influence of DNA/PEI ratios (1:1, 1:2, 1:3) and DNA/lipid ratios (1:10, 1:40) on particle properties and delivery efficiency was examined. Results: In luciferase formulations, higher DNA/lipid ratios (1:40) produced smaller particles (136 nm vs. 188 nm) with improved cellular uptake (77% vs. 50%). The two-step method with higher DNA/PEI ratios improved transfection efficiency, with LNP-Luc/PEI 1:3 (40) achieving ~1.9 × 10⁶ relative light units (RLU) in luciferase expression. In green fluorescent protein (GFP) studies, LNP-GFP/PEI 1:3 (40) showed ~23.8% GFP-positive cells, nearly twofold higher than LNP-GFP (40) at ~12.6%. Conclusions: These results demonstrate the capability of microfluidic-prepared DNA-PEI-LNPs to improve DNA delivery and transgene expression through optimized formulation strategies and selection of appropriate preparation methods. Full article

Pancreatic ductal adenocarcinoma (PDAC) is an aggressive malignancy with increasing incidence and mortality rates, highlighting the urgent need for early diagnosis and treatment. However, early diagnosis of PDAC is extremely challenging due to the atypical early symptoms or the absence of noticeable symptoms. As a result, many patients are diagnosed with local metastasis, and even patients who are eligible for surgical resection have a high postoperative recurrence rate. Consequently, chemotherapy remains the primary treatment for PDAC. However, the unique biological characteristics of PDAC not only promote tumor progression and metastasis but also often lead to chemoresistance, a significant barrier to successful treatment. Recently, nanomaterials have garnered significant attention as promising materials for diagnosing and treating PDAC, showing great potential in cancer therapy, imaging, and drug delivery. Novel targeted nanomedicines, which encapsulate chemotherapy drugs and gene therapy products, offer significant advantages in overcoming resistance. These nanomedicines not only provide innovative solutions to the limitations of conventional chemotherapy but also improve the selectivity for cancer cells to enhance therapeutic outcomes. Current research is focused on the development of advanced nanomedicines, such as liposomes, nanotubes, and polymer-lipid hybrid systems, aimed at making chemotherapy more effective and longer lasting. This review provides a detailed overview of various nanomedicines utilized in the diagnosis and treatment of PDAC and outlines future directions for their development and key breakthroughs. Full article

Cancer is considered as the second leading cause of death worldwide. Chemotherapy, radiotherapy, immunotherapy, and targeted drug delivery are the main treatment options for treating cancers. Chemotherapy drugs are either available for oral or parenteral use. Oral chemotherapy, also known as chemotherapy at home, is more likely to improve patient compliance and convenience. Oral anti-cancer drugs have bioavailability issues associated with lower aqueous solubility, first-pass metabolism, poor intestinal permeability and drug absorption, and degradation of the drug throughout its journey in the gastrointestinal tract. A highly developed carrier system known as lipid polymer hybrid nanoparticles (LPHNs) has been introduced. These nanocarriers enhance drug stability, solubility, and absorption, and reduce first-pass metabolism. Consequently, this will have a positive impact on oral bioavailability enhancement. This article provides an in-depth analysis of LPHNs as a novel drug delivery system for anti-cancer agents. It discusses an overview of the limited bioavailability of anti-cancer drugs, their reasons and consequences, LPHNs based anti-cancer drug delivery, conventional and modern preparation methods as well as their drug loading and entrapment efficiencies. In addition, this article also gives an insight into the mechanistic approach to oral bioavailability enhancement, potential applications in anti-cancer drug delivery, limitations, and future prospects of LPHNs in anti-cancer drug delivery. Full article

Edaravone is one of the treatment options for Amyotrophic Lateral Sclerosis, but its therapeutic efficacy is limited due to the incapacity to cross the blood–brain barrier, as well as its short life span and poor stability, which is ultimately caused by its tautomerism in physiological condions. This work presents an overview about the use of several nanoformulations based on polymeric, protein, lipidic, or hybrid structure as suitable and stable drug delivery systems for encapsulating edaravone. We also evaluated the functionalization of nanoparticles with pegylated chains using the polyethylene glycol or tocopherol polyethylene glycol succinate and the possibility of preparing polymeric nanoparticles at different pH (7.4, 9, and 11). Edaravone was sucessfully encapsulated in polymeric, lipid–polymer hybrid, and lipidic nanoparticles. The use of higher pH values in the synthesis of polymeric nanoparticles has led to a decrease in nanoparticle size and an increase in the percentage of encapsulation efficiency. However, the resulting nanoformulations are not stable. Only polymeric and hybrid nanoparticles showed good stability over 80 days of storage, mainly at 4 °C. Overall, the nanoformulations tested did not show cytotoxicity in the SH-SY5Y cell line except the nanostructured lipid carrier formulations that showed some cytotoxicity possibly due to lipidic peroxidation. In conclusion, this work shows that edaravone can be encapsulated in different nanocarriers that could act as an interesting alternative for the treatment of Amyotrophic Lateral Sclerosis. Full article

Background: Neratinib maleate (NM), a tyrosine kinase inhibitor, is used in the treatment of breast cancer. Current oral therapy of NM suffers from low and variable bioavailability due to the solubility and permeability-related issues of the drug. To overcome the low oral bioavailability, the drug is recommended to be administered at high doses, causing severe gastrointestinal side effects leading to discontinuation of the drug therapy. Methods: In this work, NM-loaded lipid–polymer hybrid nanoparticles (NM-LPNs) were designed and optimized to improve the oral bioavailability of the drug. A systematic approach involving a screening design followed by an optimization design based on the principles of design of experiments (DoE) was used to prepare NM-LPNs. Minimum particle size (PS) ranging between 200 and 300 nm and maximum drug loading (DL (%)) were set as the target physicochemical properties. The optimized NM-LPNs, with a mean PS of 278.57 ± 21.16 nm and a DL (%) of 25.77 ± 1.11%, were further characterized for physicochemical properties, thermal and diffractometric analysis, stability, in vitro drug release, and oral pharmacokinetic studies. Results: The nanoparticles exhibited a burst release followed by a prolonged release up to 12 h in the in vitro drug release studies in pH 6.8 media. Conclusions: The mean C_max and the AUC_last values were found to increase significantly for NM-LPNs by 1.72 times (p < 0.01) and 1.58 times (p < 0.01), respectively, when compared to plain NM in the oral pharmacokinetic studies. The optimized NM-LPN formulation can reduce the oral dose of NM and, thereby, its dose-dependent side effects. Full article

Background/Objectives: The focus of this study was to prepare and characterize docetaxel (DCX)-loaded lipid/polymer hybrid nanoparticles (LPHNps) functionalized with the monoclonal antibody (mAb) Chi-Tn for a potential active targeting approach in lung cancer treatment. Methods: We synthesized DOTAP-PLGA hybrid nanoparticles loaded with DCX and functionalized them with Chi-Tn mAb through a biotin–avidin approach. The physicochemical characterization involved dynamic light scattering, transmission electron microscopy, Raman spectroscopy, and atomic force microscopy. The in vitro and in vivo evaluations encompassed uptake studies, cell viability tests, and the assessment of tumor growth control in a lung cancer model. Results: The nanoparticles featured a hydrophobic PLGA core with 99.9% DCX encapsulation efficiency, surrounded by a DOTAP lipid shell ensuring colloidal stability with a high positive surface charge. The incorporation of PEGylated lipids on their surface helps evade the immune system and facilitate Chi-Tn mAb attachment. The resulting nanoparticles exhibit a spherical shape with monodisperse particle sizes averaging 250 nm, and demonstrate sustained drug release. In vitro uptake studies and viability assays conducted in A549 cancer cells show that the Chi-Tn mAb enhances nanoparticle internalization and significantly reduces cell viability. In vivo studies demonstrate a notable reduction in tumor volume and an increased survival rate in the A549 tumor xenograft mice model when DCX was encapsulated in nanoparticles and targeted with Chi-Tn mAb in comparison to the free drug. Conclusions: Therefore, Chi-Tn-functionalized LPHNps hold promise as carriers for actively targeting DCX to Tn-expressing carcinomas. Full article

Nanotheranostics integrates diagnostic and therapeutic functionalities using nanoscale materials, advancing personalized medicine by enhancing treatment precision and reducing adverse effects. Key materials for nanotheranostics include metallic nanoparticles, quantum dots, carbon dots, lipid nanoparticles and polymer-based nanocarriers, each offering unique benefits alongside specific challenges. Polymer-based nanocarriers, including hybrid and superparamagnetic nanoparticles, improve stability and functionality but are complex to manufacture. Polymeric nanoparticles with aggregation-induced emission (AIE) present promising theranostic potential for cancer detection and treatment. However, challenges such as translating the AIE concept to living systems, addressing toxicity concerns, overcoming deep-tissue imaging limitations, or ensuring biocompatibility remain to be resolved. Recently, cluster-triggered emission (CTE) polymers have emerged as innovative materials in nanotheranostics, offering enhanced fluorescence and biocompatibility. These polymers exhibit increased fluorescence intensity upon aggregation, making them highly sensitive for imaging and therapeutic applications. CTE nanoparticles, crafted from biodegradable polymers, represent a safer alternative to traditional nanotheranostics that rely on embedding conventional fluorophores or metal-based agents. This advancement significantly reduces potential toxicity while enhancing biocompatibility. The intrinsic fluorescence allows real-time monitoring of drug distribution and activity, optimizing therapeutic efficacy. Despite their potential, these systems face challenges such as maintaining stability under physiological conditions and addressing the need for comprehensive safety and efficacy studies to meet clinical and regulatory standards. Nevertheless, their unique properties position CTE nanoparticles as promising candidates for advancing theranostic strategies in personalized medicine, bridging diagnostic and therapeutic functionalities in innovative ways. Full article

Background/Objectives: Following tooth extraction, resveratrol (RSV) can support healing by reducing inflammation and microbial risks, though its poor solubility limits its effectiveness. This study aims to develop a solid nanocomposite by embedding RSV in lipid nanoparticles (mLNP) within a hydrophilic matrix, to the scope of improving local delivery and enhancing healing. Hydroxyapatite (HXA), often used as a bone substitute, was added to prevent post-extraction alveolus volume reduction. Methods: The mLNP-RSV dispersion was mixed with seven different polymers in various mLNP/polymer ratios. Following freeze-drying, the powders were redispersed, and the resulting dispersions were tested by DLS experiments. Then, the best two nanocomposites underwent extensive characterization by SEM, XRD, FTIR, Raman spectroscopy, and thermal analysis as well as in vitro partitioning studies aimed at verifying their ability to yield the mLNP-RSV from the hydrophilic matrix to a lipophilic tissue. The characterizations led to identify the best nanocomposite, which was further combined with HXA to obtain hybrid nanocomposites, further evaluated as pharmaceutical powders or in form of mini-tablets. Results: PEG-based nanocomposites emerged as optimal and, following HXA insertion, the resulting powders revealed adequate bulk properties, making them useful as a pharmaceutical intermediate to produce ≈59 mm³ mini-tablets, compliant with the post-extraction socket. Moreover, they were proven ex vivo to be able to promote RSV and GA accumulation into the buccal tissue over time. Conclusions: The here-proposed mini-tablet offers an innovative therapeutic approach for alveolar wound healing promotion as they led to a standardized dose administration, while being handy and stable in terms of physical solid identity as long as it takes to suture the wound. Full article

Background. Lipid–polymer hybrid nanoparticles (LPHNPs) offer a promising method for delivering methylprednisolone (MePD) to treat lung inflammation, addressing aggregation issues seen with polymer-only formulations. Objectives. This study aimed to develop LPHNPs for MePD delivery, assessing their physicochemical properties, drug loading, cytocompatibility, and release profiles, ultimately enabling inhalable microparticle-based powder. Methods. The nanoparticles were formulated using α,β-poly(N-2-hydroxyethyl)-DL-aspartamide-g-Rhodamine B-g-poly(lactic acid) (PHEA-g-RhB-g-PLA) and phospholipids DPPC, DOTAP, and DSPE-PEG2000 in a 45:30:25 weight ratio. Their size, redispersion after freeze-drying, drug loading (DL%), and controlled release were evaluated. Cytocompatibility was assessed on 16-HBE cell lines, measuring anti-inflammatory effects via IL-6 and IL-8 levels. Spray drying was optimized to produce microparticles using mannitol (MAN), leucine (LEU), and N-acetylcysteine (NAC). Results. The nanoparticles had a size of 186 nm and a DL% of 2.9% for MePD. They showed good cytocompatibility, significantly reducing IL-6 and IL-8 levels. Spray drying yielded microparticles with a fine particle fraction (FPF) of 62.3% and a mass median aerodynamic diameter (MMAD) of 3.9 µm. Inclusion of LPHNPs@MePD (0.25% w/v) resulted in FPF and MMAD values of 56.7% and 4.4 µm. In conclusion, this study described the production of novel inhalable powders as carriers for MePD-loaded nanostructures with favorable physicochemical properties, cytocompatibility, and promising aerosol performance, indicating their potential as an effective inhalable therapy for lung inflammation with corticosteroids, especially for treating chronic diseases. Full article