Drug Delivery Monitoring Research Articles

Azo-linked 5-ASA-coumarin prodrug: Fluorescent tracking for colonic drug release in UC treatment

Theranostic prodrugs that enable real-time, non-invasive monitoring of drug release and biodistribution are highly desirable for optimizing therapeutic efficacy and guiding personalized medication. Herein, we report a colon-targeted theranostic prodrug system (P1) for the simultaneous delivery and tracking of 5-aminosalicylic acid (5-ASA) in the treatment of ulcerative colitis (UC). P1 comprises a fluorescent 7-amino-4-methylcoumarin (7-AMC) reporter covalently linked to 5-ASA via an azo bond, which quenches the fluorescence of 7-AMC until P1 is activated by azoreductases in the colonic microenvironment. This selective activation triggers the release of 5-ASA and the revival of 7-AMC fluorescence, enabling real-time monitoring of drug delivery. To improve the solubility and targeted delivery of P1, it was encapsulated within polymeric micelles (PM) that selectively adhere to the positively charged, inflamed colonic tissues. In vitro studies confirmed the stability, biocompatibility, and selective activation of P1 under simulated colonic conditions. Notably, in a mouse model of UC, the P1-loaded PM achieved targeted delivery of 5-ASA to the inflamed colon, resulting in effective attenuation of colitis symptoms. Importantly, the in situ activation of P1 allowed for the real-time, non-invasive visualization of drug release and biodistribution, providing valuable insights for treatment optimization. This theranostic prodrug approach offers a promising strategy for the simultaneous therapy and tracking of 5-ASA delivery in UC treatment, with the potential to facilitate personalized medication and improve therapeutic outcomes.

Review on Photoacoustic Monitoring after Drug Delivery: From Label-Free Biomarkers to Pharmacokinetics Agents.

Photoacoustic imaging (PAI) is an emerging noninvasive and label-free method for capturing the vasculature, hemodynamics, and physiological responses following drug delivery. PAI combines the advantages of optical and acoustic imaging to provide high-resolution images with multiparametric information. In recent decades, PAI's abilities have been used to determine reactivity after the administration of various drugs. This study investigates photoacoustic imaging as a label-free method of monitoring drug delivery responses by observing changes in the vascular system and oxygen saturation levels across various biological tissues. In addition, we discuss photoacoustic studies that monitor the biodistribution and pharmacokinetics of exogenous contrast agents, offering contrast-enhanced imaging of diseased regions. Finally, we demonstrate the crucial role of photoacoustic imaging in understanding drug delivery mechanisms and treatment processes.

Nanocomposite Hydrogel for Real-Time Wound Status Monitoring and Comprehensive Treatment.

Current skin sensors or wound dressings fall short in addressing the complexities and challenges encountered in real-world scenarios, lacking adequate capability to facilitate wound repair. The advancement of methodologies enabling early diagnosis, real-time monitoring, and active regulation of drug delivery for timely comprehensive treatment holds paramount significance for complex chronic wounds. In this study, a nanocomposite hydrogel is devised for real-time monitoring of wound condition and comprehensive treatment. Tannins and siRNA containing matrix metalloproteinase-9 gene siRNA interference are self-assembled to construct a degradable nanogel and modified with bovine serum albumin. The nanogel and pH indicator are encapsulated within a dual-crosslinking hydrogel synthesized with norbornene dianhydride-modified paramylon. The hydrogel exhibited excellent shape adaptability due to borate bonding, and the click polymerization reaction led to rapid in situ curing of the hydrogel. The system not only monitors pH, temperature, wound exudate alterations, and peristalsis during wound healing but also exhibits hemostatic, antimicrobial, anti-inflammatory, and antioxidant properties, modulates macrophage polarization, and facilitates vascular tissue regeneration. This therapeutic approach, which integrates the monitoring of pathological parameters with comprehensive treatment, is anticipated to address the clinical issues and challenges associated with chronic diabetic wounds and infected wounds, offering broad prospects for application.

Co-delivery of camptothecin and MiR-145 by lipid nanoparticles for MRI-visible targeted therapy of hepatocellular carcinoma

BackgroundCamptothecin (CPT) is one of the frequently used small chemotherapy drugs for treating hepatocellular carcinoma (HCC), but its clinical application is limited due to severe toxicities and acquired resistance. Combined chemo-gene therapy has been reported to be an effective strategy for counteracting drug resistance while sensitizing cancer cells to cytotoxic agents. Thus, we hypothesized that combining CPT with miR-145 could synergistically suppress tumor proliferation and enhance anti-tumor activity.MethodsLactobionic acid (LA) modified lipid nanoparticles (LNPs) were developed to co-deliver CPT and miR-145 into asialoglycoprotein receptors-expressing HCC in vitro and in vivo. We evaluated the synergetic antitumor effect of miR-145 and CPT using CCK8, Western blotting, apoptosis and wound scratch assay in vitro, and the mechanisms underlying the synergetic antitumor effects were further investigated. Tumor inhibitory efficacy, safety evaluation and MRI-visible ability were assessed using diethylnitrosamine (DEN) + CCl4-induced HCC mouse model.ResultsThe LA modification improved the targeting delivery of cargos to HCC cells and tissues. The LA-CMGL-mediated co-delivery of miR-145 and CPT is more effective on tumor inhibitory than LA-CPT-L or LA-miR-145-L treatment alone, both in vitro and in vivo, with almost no side effects during the treatment period. Mechanistically, miR-145 likely induces apoptosis by targeting SUMO-specific peptidase 1 (SENP1)-mediated hexokinase (HK2) SUMOylation and glycolysis pathways and, in turn, sensitizing the cancer cells to CPT. In vitro and in vivo tests confirmed that the loaded Gd-DOTA served as an effective T1-weighted contrast agent for noninvasive tumor detection as well as real-time monitoring of drug delivery and biodistribution.ConclusionsThe LA-CMGL-mediated co-delivery of miR-145 and CPT displays a synergistic therapy against HCC. The novel MRI-visible, actively targeted chemo-gene co-delivery system for HCC therapy provides a scientific basis and a useful idea for the development of HCC treatment strategies in the future.

Harnessing Biopolymer Gels for Theranostic Applications: Imaging Agent Integration and Real-Time Monitoring of Drug Delivery.

Biopolymer gels have gained tremendous potential for therapeutic applications due to their biocompatibility, biodegradability, and ability to adsorb and bind biological fluids, making them attractive for drug delivery and therapy. In this study, the versatility of biopolymer gels is explored in theranostic backgrounds, with a focus on integrating imaging features and facilitating real-time monitoring of drug delivery. Different methods of delivery are explored for incorporating imaging agents into biopolymer gels, including encapsulation, surface functionalization, nanoparticle encapsulation, and layer-by-layer assembly techniques. These methods exhibit the integration of agents and real-time monitoring drug delivery. We summarize the synthesis methods, general properties, and functional mechanisms of biopolymer gels, demonstrating their broad applications as multimodal systems for imaging-based therapeutics. These techniques not only enable multiple imaging but also provide signal enhancement and facilitate imaging targets, increasing the diagnostic accuracy and therapeutic efficacy. In addition, current techniques for incorporating imaging agents into biopolymer gels are discussed, as well as their role in precise drug delivery and monitoring.

Emerging Trends in Targeted Magnetic Nanoparticle Imaging for Precision Medicine in Oncology

In cancer care's dynamic landscape, targeted imaging is pivotal for advancing precision medicine. This review focuses on the role of magnetic nanoparticles (MNPs), particularly magnetic iron oxide nanoparticles (MIONPs) and superparamagnetic iron oxide nanoparticles (SPIONs), in personalized diagnostics and treatments for oncology. Current trends and future directions in MNP imaging, addressing challenges like biocompatibility, toxicity, and regulatory considerations, are discussed. The review explores MIONPs' theranostic potential, especially in brain drug delivery monitoring through magnetic resonance imaging (MRI) or magnetic particle imaging (MPI). Variousnanoparticle types, including SPIONs as MRI contrast agents, are highlighted. The article covers challenges in nanoparticle modification, including methoxy- polyethylene glycol (mPEG), and discusses gold nanoparticles (AuNPs) for photoacoustic imaging, as well as insights into fluorescent semiconductor quantum dots (QDs). The conclusion emphasizes rapid and accurate tumoridentification, introduces carbon nanotubes (CNTs) for cancer therapy and diagnosis, and underscores the transformative role of lipid-based nanocarriers incancer research. The multifaceted applications of nanotechnology in cancer diagnostics and treatment are discussed throughout, showcasing a paradigm shift.Crucial challenges in unlocking nanotechnology's full potential in cancer care, such as safety concerns, robust clinical trials, synthesis methods standardization, regulatory approval, biodegradability, tailoring nanotherapies, economic viability, ethical considerations, and interdisciplinary collaboration, are addressed. Addressing these challenges holds the promise of elevating nanotechnology into a potent force in the ongoing battle against cancer.

Vat photopolymerization printing of functionalized hydrogels on commercial contact lenses

Contact lenses are widely used for vision correction and cosmetic purposes. Smart contact lenses offer further opportunities as functionalized non-invasive devices capable of simultaneous vision correction, real-time health monitoring and patient specific drug delivery. Herein, a low-cost vat photopolymerization technique is developed for directly 3D printing functionalized structures on commercially available contact lenses. The process enables controlled deposition of functionalized hydrogels, in customizable patterns, on the commercial contact lens surface with negligible optical losses. Multi-functional contact lenses can also be 3D printed with multiple materials deposited at different regions of the contact lens. Herein, the functionalities of colour blindness correction and real-time UV monitoring are demonstrated, by employing three suitable dyes incorporated into 2-hydroxyethyl methacrylate (HEMA) hydrogel structures printed on contact lenses. The results suggest that 3D printing can pave the way towards simple production of low-cost patient specific smart contact lenses.

Noninvasive ROS imaging and drug delivery monitoring in the tumor microenvironment

Reactive oxygen species (ROS) that are overproduced in certain tumors can be considered an indicator of oxidative stress levels in the tissue. Here, we report a magnetic resonance imaging (MRI)-based probe capable of detecting ROS levels in the tumor microenvironment (TME) using ROS-responsive manganese ion (Mn2+)-chelated, biotinylated bilirubin nanoparticles (Mn@bt-BRNPs). These nanoparticles are disrupted in the presence of ROS, resulting in the release of free Mn2+, which induces T1-weighted MRI signal enhancement. Mn@BRNPs show more rapid and greater MRI signal enhancement in high ROS-producing A549 lung carcinoma cells compared with low ROS-producing DU145 prostate cancer cells. A pseudo three-compartment model devised for the ROS-reactive MRI probe enables mapping of the distribution and concentration of ROS within the tumor. Furthermore, doxorubicin-loaded, cancer-targeting ligand biotin-conjugated Dox/Mn@bt-BRNPs show considerable accumulation in A549 tumors and also effectively inhibit tumor growth without causing body weight loss, suggesting their usefulness as a new theranostic agent. Collectively, these findings suggest that Mn@bt-BRNPs could be used as an imaging probe capable of detecting ROS levels and monitoring drug delivery in the TME with potential applicability to other inflammatory diseases.

Real-Time Particle Emission Monitoring for the Non-Invasive Prediction of Lung Deposition via a Dry Powder Inhaler

Although inhalation therapy represents a promising drug delivery route for the treatment of respiratory diseases, the real-time evaluation of lung drug deposition remains an area yet to be fully explored. To evaluate the utility of the photo reflection method (PRM) as a real-time non-invasive monitoring of pulmonary drug delivery, the relationship between particle emission signals measured by the PRM and in vitro inhalation performance was evaluated in this study. Symbicort® Turbuhaler® was used as a model dry powder inhaler. In vitro aerodynamic particle deposition was evaluated using a twin-stage liquid impinger (TSLI). Four different inhalation patterns were defined based on the slope of increased flow rate (4.9–9.8 L/s2) and peak flow rate (30 L/min and 60 L/min). The inhalation flow rate and particle emission profile were measured using an inhalation flow meter and a PRM drug release detector, respectively. The inhalation performance was characterized by output efficiency (OE, %) and stage 2 deposition of TSLI (an index of the deagglomerating efficiency, St2, %). The OE × St2 is defined as the amount delivered to the lungs. The particle emissions generated by four different inhalation patterns were completed within 0.4 s after the start of inhalation, and were observed as a sharper and larger peak under conditions of a higher flow increase rate. These were significantly correlated between the OE or OE × St2 and the photo reflection signal (p < 0.001). The particle emission signal by PRM could be a useful non-invasive real-time monitoring tool for dry powder inhalers.Graphical

Advanced Dressings for Chronic Wound Management.

Wound healing, particularly for chronic wounds, presents a considerable difficulty due to differences in biochemical and cellular processes that occur in different types of wounds. Recent technological breakthroughs have notably advanced the understanding of diagnostic and therapeutic approaches to wound healing. The evolution in wound care has seen a transition from traditional textile dressings to a variety of advanced alternatives, including self-healing hydrogels, hydrofibers, foams, hydrocolloids, environment responsive dressings, growth factor-based therapy, bioengineered skin substitutes, and stem cell and gene therapy. Technological advancements, such as 3D printing and electronic skin (e-skin) therapy, contribute to the customization of wound healing. Despite these advancements, effectively managing chronic wounds remains challenging. This necessitates the development of treatments that consider performance, risk-benefit balance, and cost-effectiveness. This review discusses innovative strategies for the healing of chronic wounds. Incorporating biomarkers into advanced dressings, coupled with corresponding biosensors and drug delivery formulations, enables the theranostic approach to the treatment of chronic wounds. Furthermore, integrating advanced dressings with power sources and user interfaces like near-field communication, radio frequency identification, and Bluetooth enhances real-time monitoring and on-demand drug delivery. It also provides a thorough evaluation of the advantages, patient compliance, costs, and durability of advanced dressings, emphasizing smart formulations and their preparation methods.

Monitoring the Degradation of Metal‐Organic Framework Drug Nanocarriers by In‐Situ NMR Spectroscopy

AbstractAn accurate characterization methodology is indispensable to design nanoparticle‐based drug delivery system (DDS) adapted to specific diseases and therapies. However, characterization techniques employed to investigate drug release and nanoparticle degradation require separating the nanoparticles from their suspension media, which can lead to artefacts. Therefore, there is a clear need to implement novel versatile in‐situ methods. Here, we report the use of in‐situ NMR spectroscopy to monitor drug delivery processes from MOF nanocarriers, both in solution and in the solid state simultaneously. In‐situ 1H NMR investigation of nanoMIL‐100(Al) suspension in phosphate medium enabled recording the trimesate ligand loss in the solid phase and the ligand release in the liquid phase as a function of time. Simultaneously, 27Al NMR enabled assessing the progressive replacement of carboxylate ligands by phosphates leading to the formation of new aluminum species. Using the same strategy, we also compared the degradation of nanoMIL‐100(Al) loaded with two drug analogs, highlighting an effect of metal‐ligand complexing strength. Furthermore, our in‐situ technique is applicable to studying the reaction of paramagnetic nanoMIL‐100(Fe) in the liquid phase. This work offers an alternative to ex‐situ techniques for understanding the degradation mechanism of MOF nanocarriers and could be an asset for other nanoscale DDSs.

Methotrexate-loaded manganese nitrogen dual-doped carbon quantum dots as targeted nano drug-delivery system for potential use in cancer theranostics

The present work highlights manganese nitrogen dual-doped carbon quantum dots as a novel pH-sensitive drug delivery system, for the delivery of methotrexate, targeted to cancer cells, along with the simultaneous real-time monitoring of cellular uptake and drug delivery using fluorescence imaging. Briefly, methotrexate was conjugated with the as-prepared quantum dots to form a nano drug-delivery system through non-covalent interactions. The developed material demonstrated drug loading efficiency of ∼91 % and a very efficient (∼80 %) pH-responsive drug release at pH 5.5. The cytotoxic properties of the developed nano-platform viz. manganese, nitrogen dual-doped carbon quantum dots, and methotrexate conjugated manganese nitrogen dual-doped carbon quantum dot complex were evaluated in cancer cells (HeLa) and healthy human cells (L929). The conjugated complex demonstrated excellent biocompatibility, high cellular uptake, and a substantial drug release. Healthy human cells were largely unaffected when incubated with both the MTX-conjugated Mn-, N-CQD and the free drug. Additionally, in vitro, the fluorescence bio-imaging potential of the developed nano-platform was also assessed, where the unconjugated (free) quantum dots exhibited better blue fluorescence imaging potential compared to that of the conjugated complex, which can be attributed to fluorescence quenching due to the presence of methotrexate. This study highlights the manganese nitrogen dual-doped carbon quantum dots capable of pH-responsive methotrexate drug delivery selective to cancer cells. The combination of drug delivery and fluorescence imaging creates an efficient platform for targeted therapy, allowing very precise drug release while accessing non-invasive monitoring of therapeutic response. This method holds a great promise for advancing cancer treatment strategies, with the potential for increased efficacy and decreased side effects.

MXene/TPU Hybrid Fabrics Enable Smart Wound Management and Thermoresponsive Drug Delivery.

Thermoresponsive wound dressings with real-time monitoring and on-demand drug delivery have gained significant attention recently. However, such smart systems with stable temperature adjustment and drug release control are still lacking. Here, a novel smart fabric is designed for wound management with thermoresponsive drug delivery and simultaneously temperature monitoring. The triple layers of the fabrics are composed of the drug-loaded thermoresponsive nanofiber film, the MXene-optimized joule heating film, and the FPCB control chip. The precise and stable temperature stimulation can be easily achieved by applying a low voltage (0-4 V) to the heating film, achieving the temperature control ranging from 25 to 130 °C. And the temperature of the wound region can be monitored and adjusted in real time, demonstrating an accurate and low-voltage joule heating capability. Based on that, the drug-loaded film achieved precise thermoresponsive drug release and obtained significant antibacterial effects in vitro. The in vivo experiments also proved the hybrid fabric system with a notable antibacterial effect and accelerated wound healing process (about 30% faster than the conventional gauze group).

Separable Microneedle for Integrated Hyperglycemia Sensing and Photothermal Responsive Metformin Release.

Microdevices that offer hyperglycemia monitoring and controllable drug delivery are urgently needed for daily diabetes management. Herein, a theranostic separable double-layer microneedle (DLMN) patch consisting of a swellable GelMA supporting base layer for glycemia sensing and a phase-change material (PCM) arrowhead layer for hyperglycemia regulation has been fabricated. The Cu-TCPP(Fe)/glucose oxidase composite and 3,3',5,5'-tetramethylbenzidine coembedded in the supporting base layer permit a visible color shift at the base surface in the presence of glucose via a cascade reaction, allowing for the in situ detection of glucose in interstitial fluid. The PCM arrowhead layer is encapsulated with water monodispersity melanin nanoparticles from Sepia officinalis and metformin that is imparted with a near-infrared ray photothermal response feature, which is beneficial to the controllable release of metformin for suppression of hyperglycemia. By applying the DLMN patch to the streptozotocin-induced type 2 diabetic Sprague-Dawley rat model, the results demonstrated that it can effectively extract dermal interstitial fluid, read out glucose levels, and regulate hyperglycemia. This DLMN-integrated portable colorimetric sensor and self-regulated glucose level hold great promise for daily diabetes management.

Breaking Barriers in Neuro-Oncology: A Scoping Literature Review on Invasive and Non-Invasive Techniques for Blood-Brain Barrier Disruption.

The blood-brain barrier (BBB) poses a significant challenge to drug delivery for brain tumors, with most chemotherapeutics having limited permeability into non-malignant brain tissue and only restricted access to primary and metastatic brain cancers. Consequently, due to the drug's inability to effectively penetrate the BBB, outcomes following brain chemotherapy continue to be suboptimal. Several methods to open the BBB and obtain higher drug concentrations in tumors have been proposed, with the selection of the optimal method depending on the size of the targeted tumor volume, the chosen therapeutic agent, and individual patient characteristics. Herein, we aim to comprehensively describe osmotic disruption with intra-arterial drug administration, intrathecal/intraventricular administration, laser interstitial thermal therapy, convection-enhanced delivery, and ultrasound methods, including high-intensity focused and low-intensity ultrasound as well as tumor-treating fields. We explain the scientific concept behind each method, preclinical/clinical research, advantages and disadvantages, indications, and potential avenues for improvement. Given that each method has its limitations, it is unlikely that the future of BBB disruption will rely on a single method but rather on a synergistic effect of a combined approach. Disruption of the BBB with osmotic infusion or high-intensity focused ultrasound, followed by the intra-arterial delivery of drugs, is a promising approach. Real-time monitoring of drug delivery will be necessary for optimal results.

Emerging microelectronic microneedles (eMN) for biomedical applications

As emerging medical tool microneedles have attracted significant attention since puncture the skin noninvasively and painlessly, facilitating tasks such as physiological monitoring, disease diagnosis, and transdermal drug delivery.

Soft, Long-Lived, Bioresorbable Electronic Surgical Mesh with Wireless Pressure Monitor and On-Demand Drug Delivery.

Current research in the area of surgical mesh implants is somewhat limited to traditional designs and synthesis of various mesh materials, whereas meshes with multiple functions may be an effective approach to address long-standing challenges including postoperative complications. Herein, a bioresorbable electronic surgical mesh is presented that offers high mechanical strength over extended timeframes, wireless post-operative pressure monitoring, and on-demand drug delivery for the restoration of tissue structure and function. The study of materials and mesh layouts provides a wide range of tunability of mechanical and biochemical properties. Dissolvable dielectric composite with porous structure in a pyramidal shape enhances sensitivity of a wireless capacitive pressure sensor, and resistive microheaters integrated with inductive coils provide thermo-responsive drug delivery system for an antibacterial agent. In vivo evaluations demonstrate reliable, long-lived operation, and effective treatment for abdominal hernia defects, by clear evidence of suppressed complications such as adhesion formation and infections.

Thermodynamic Characterization of the Interaction of Biofunctionalized Gold Nanoclusters with Serum Albumin Using Two- and Three-Dimensional Methods

Fluorescent gold nanoclusters have been successfully used as fluorescent markers for imaging of cells and tissues, and their potential role in drug delivery monitoring is coming to the fore. In addition, the development of biosensors using structure-tunable fluorescent nanoclusters is also a prominent research field. In the case of these sensor applications, the typical goal is the selective identification of, e.g., metal ions, small molecules having neuroactive or antioxidant effects, or proteins. During these application-oriented developments, in general, there is not enough time to systematically examine the interaction between nanoclusters and relevant biomolecules/proteins from a thermodynamic viewpoint. In this way, the primary motivation of this article is to carry out a series of tests to partially fill this scientific gap. Besides the well-known fluorescent probes, the mentioned interactions were investigated using such unique measurement methods as surface plasmon resonance (SPR) and isothermal titration calorimetry (ITC). These two-dimensional (at the solid/liquid interface) and three-dimensional (in the bulk phase) measuring techniques provide a unique opportunity for the thermodynamic characterization of the interaction between different gold nanoclusters containing various surface functionalizing ligands and bovine serum albumin (BSA).

A Novel PEtOx-Based Nanogel Targeting Prostate Cancer Cells for Drug Delivery.

This study focuses on creating a specialized nanogel for targeted drug delivery in cancer treatment, specifically targeting prostate cancer. This nanogel (referred to as SGK 636/Peptide 563/PEtOx nanogel) is created using hydrophilic poly(2-ethyl-2-oxazoline) (PEtOx) through a combination of living/cationic ring-opening polymerization (CROP) and alkyne-azide cycloaddition (CuAAC) "click" chemical reactions. A fluorescent probe (BODIPY) is also conjugated with the nanogel to monitor drug delivery. The characterizations through 1 H-NMR, and FT-IR, SEM, TEM, and DLS confirm the successful production of uniform, and spherical nanogels with controllable sizes (100 to 296nm) and stability in physiological conditions. The biocompatibility of nanogels is evaluated using MTT cytotoxicity assays, revealing dose-dependent cytotoxicity. Drug-loaded nanogels exhibited significantly higher cytotoxicity against cancer cells in vitro compared to drug-free nanogels. Targeting efficiency is examined using both peptide-conjugated and peptide-free nanogels, with the intracellular uptake of peptide 563-conjugated nanogels by tumor cells being 60-fold higher than that of nanogels without the peptide. The findings suggest that the prepared nanogel holds great potential for various drug delivery applications due to its ease of synthesis, tunable functionality, non-toxicity, and enhanced intracellular uptake in the tumor region.

Evaluation of betanin-encapsulated biopolymeric nanoparticles for antitumor activity via PI3K/Akt/mTOR signaling pathway

Cancer nanotheranostic components are useful in monitoring drug delivery and potency against tumor cells. Current chemotherapeutic agents exhibit severe side effects and requires the urgency for discovery of potent therapeutic nano-drugs. So, this study focuses on evaluating the antitumor activity of chitosan nanoparticles encapsulating betanin (CSNPs-BET) against breast cancer (MDA-MB-231) cells. CSNPs-BET were prepared using the ionic gelation method and characterized for their size, polydispersity index (PDI), zeta potential, and surface morphology. Antitumor activity of CSNPs-BET and standard drug, doxorubicin (DOX), was evaluated using MTT, cell migration and gene expression assays. The entrapment efficiency of CSNPs-BET was in the approximate range of 88–91%. The sustained in vitro betanin release pattern was observed under different conditions. Chitosan nanoparticles encapsulated with and without betanin reduced the cell viability in MDA-MB-231 cells with IC50 values of 3.974 µg/mL and 7.994 µg/mL, respectively. Further, the treatment of MDA-MB-231 with CSNPs-BET with different concentrations significantly reduced the levels of PI3K (**P = 0.0016), Akt (**P = 0.0014) and mTOR (****P < 0.0001) as compared to control. Inhibition of PI3K and downstream molecules Akt and mTOR by CSNPs-BET resulted in cell proliferation inhibition and cell cycle arrest. Furthermore, CSNPs-BET treated MDA-MB-231 cells probed the significant two-dimensional migration of cells vs. control. Our study findings suggest that nano-scale formulation can improve systematic toxicity and cell proliferation inhibitory activity against cancer cells. In conclusion, the CSNPs-BET improved MDA-MB-231 cells death and depicts promising nano-therapy for breast cancer.