Magnetic Nanoparticles Research Articles

Simultaneous detection of myostatin-targeting monoclonal antibodies in dried blood spots and plasma using liquid chromatography-tandem mass spectrometry with field asymmetric ion mobility spectrometry

Transforming growth factor-β superfamily members, such as myostatin, growth/differentiation factor 11, and activin A, negatively regulate skeletal muscle mass. Inhibitors targeting these cytokines or activin receptor type IIB have the potential to treat muscular diseases and enhance physical performance. However, because of their effects on muscle mass and potential misuse, they are strictly prohibited in sports. Given the high potential for misuse as a doping agent in sports, effective analytical methods for these prohibited antibodies targeting these specific cytokines or their receptor are critically needed. In this study, we aimed to develop and validate a multitarget method to detect the prohibited transforming growth factor-β superfamily-targeting monoclonal antibodies, such as landogrozumab, domagrozumab, and the activin receptor type IIB-targeting antibody, bimagrumab, in human plasma and dried blood spot (DBS) samples using liquid chromatography-tandem mass spectrometry. Antibodies were purified from both the DBS and plasma samples using protein G magnetic beads and field-asymmetric ion mobility spectrometry (FAIMS) to minimize interference, followed by liquid chromatography-tandem mass spectrometry analysis. The validation process included tests for specificity, selectivity, linearity, limit of detection (LOD), limit of identification, precision, recovery, carryover effect, and matrix effect. The LODs for the target antibodies were identical in both DBS and plasma samples at 0.1 µg/mL for landogrozumab heavy and light chains, as well as 0.25 µg/mL for the domagrozumab light chain and 0.25 µg/mL for the bimagrumab heavy chain. However, the heavy chain of domagrozumab exhibited an LOD of 0.5 µg/mL in DBS and 1 µg/mL in plasma. The analytical method demonstrated strong linearity, with R² values greater than 0.99 for both plasma and DBS, and no carryover effect. Precision (CV%) was below 15 % at both middle (1 or 5 µg/mL; specific to the heavy chain of domagrozumab in plasma) and high (10 µg/mL) concentrations and was less than 20 % at the LOD. The selectivity and specificity indicated no interference in the analysis of target mAbs in different blood samples. Recovery was 31.6–49.8 % for DBS and 51.4–85.3 % for plasma, with no significant matrix effect. This study provides an effective method for doping analysis and novel protein detection.

Changes in gene expression profile of normal human fibroblasts on P(VDF-TrFE) scaffolds highly doped with Fe3O4-CA nanoparticles under alternating magnetic field stimulation

The design of novel hybrid magnetoactive scaffolds based on biocompatible piezopolymers and magnetic nanoparticles is of interest for medicine, mainly for tissue regeneration, because application of an external either static or alternating magnetic field to cells that settled on a magnetoactive scaffold offers an opportunity for remote control of cellular functions. This study describes fabrication of electrospun magnetoactive poly(vinylidene fluoride-co-trifluoroethylene) [P(VDF-TrFE)] scaffolds highly doped with 20 wt% of magnetite nanoparticles modified with citric acid (Fe3O4-CA). The electrospun P(VDF-TrFE)/Fe3O4-CA scaffolds have defect-free morphology with a fiber diameter of approximately 1 μm and contain both an electroactive β-phase (predominantly) and a lesser amount of an γ-phase. A high content of uniformly distributed Fe3O4-CA nanoparticles within P(VDF-TrFE) fibrous scaffolds resulted in a high saturation magnetization of 12.1 emu/g and ferrimagnetic behavior of the composite P(VDF-TrFE)/Fe3O4-CA scaffolds. They were proved to be biocompatible with normal human cells: normal human fibroblasts and human mesenchymal stem cells adhered to the scaffold and retained their viability. According to high-throughput RNA-sequencing data, the adhesion of fibroblasts to the scaffolds upregulated genes related to key stages of tissue regeneration such as coagulation (genes THBD and SERPINB2) and wound healing (IL24, PDGFB, F3, and PLAU) and affected TGFβ, BMP, and Wnt signaling pathways. Alternating-magnetic-field exposure of the magnetoactive P(VDF-TrFE)/Fe3O4-CA scaffolds with fibroblasts settled on the surface activated extracellular and intracellular cell signaling pathways.

Picotesla optically pumped magnetometer using a laser-written vapor cell with sub-mm cross section

We demonstrate a sensitive optically pumped magnetometer using rubidium vapor and 0.75 amg of nitrogen buffer gas in a sub-mm-width sensing channel excavated by femtosecond laser writing followed by chemical etching. The channel is buried less than 1 mm below the surface of its fused silica host material, which also includes reservoir chambers and micro-strainer connections, to preserve a clean optical environment. Using a zero-field-resonance magnetometry strategy and a sensing volume of 2.25 mm3, we demonstrate a sensitivity of ≈1pT/Hz at 10 Hz. The device can be integrated with photonic structures and microfluidic channels with 3D versatility. Its sensitivity, bandwidth, and stand-off distance will enable detection of localized fields from magnetic nanoparticles and μL NMR samples.

Production of invertase from Penicillium spp. under solid state fermentation and its immobilization on magnetic nanoparticles

Invertase is an industrially significant enzyme that catalyzes the hydrolysis of sucrose into glucose and fructose. The present work aimed to produce invertase from Penicillium spp. under solid-state fermentation, utilizing banana peel waste as the substrate, and to characterize and immobilize the enzyme using chitosan-coated magnetic nanoparticles. The partially purified invertase was obtained via ammonium sulfate precipitation. The stability of crude, partially purified, and immobilized invertase was assessed for various parameters such as pH, temperature, thermal stability, metal ions, and chemical inhibitors. Invert syrup was produced via continuous bioconversion. The optimal incubation period for invertase production was observed to be four days, resulting in a maximum invertase activity of 75 U/ml. The maximum activities of the crude and partially purified invertase were observed at pH 6, temperature 50°C, and metal ion KCl, while the chemical inhibitor EDTA enhanced the activity. Partial purification of the crude invertase with 70% ammonium sulfate yielded 49 U/ml, and immobilization on chitosan-coated magnetic nanoparticles resulted in a 59.01% immobilized yield. The maximum immobilized invertase activity was observed at 70°C, and the immobilization procedure did not significantly influence pH, metal ions, or chemical inhibitor activity. Invert syrup production via continuous bioconversion resulted in an enzyme activity of 31 U/ml. This study highlights the potential applications of invertase in the food industry, pharmaceuticals, confectionaries, and related fields.

Oriental covalent immobilization of N-glycan binding protein via N-terminal selective modification

Lectin affinity chromatography is one of powerful tools for the study of protein glycosylation. Different lectin proteins can recognize different structures of monosaccharides or oligosaccharide units, allowing for the selective separation of glycopeptides or glycoproteins containing different polysaccharide structures. However, the N-glycans were only partially captured by most of common lectins, reducing the coverage rate of identifying N-glycoconjugates. Recently, it has been reported that the engineering variant of glycan binding protein Fbs1 has a high affinity for innermost Man3GlcNAc2 structure and is able to bind diverse types of N-glycans, which can be suitable for the analysis of protein N-glycosylation. However, efficient immobilization of protein to separation matrix is particularly challenging as it requires the functionality and integrity of the protein to be preserved. Herein, we describe a simple and robust strategy for oriental covalent immobilization of proteins on magnetic nanoparticles by N-terminal selective labeling techniques. We inserted the enterokinase cleavage site to produce the specific N- terminal glycine of protein. Under physiological conditions, the protein was immobilized on the surface of the MNPs by this glycine tag, and the enrichment process could be completed within 30 min. A whole enrichment and purification of glycan and glycopeptides were completed and analyzed by MALDI TOF-MS. The functional materials achieved stable enrichment of glycan structure in different enzyme digestion systems or complex samples, showing excellent anti-interference and applicability.

A fluorescent platform integrated with a “one-pot” nicking endonuclease signal amplification and magnetic separation for simultaneous detection of tumor markers

Although Enzyme-linked immunosorbent assay (ELISA) has been widely used for biomedical research, simultaneous sensitive and cost-effective detection of multiple biomarkers is challenging. Herein, we proposed a “one-pot” nicking endonuclease signal amplification (NESA)-based fluorescent aptasensor for simultaneous detection of carcinoembryonic antigen (CEA) and alpha fetoprotein (AFP). Firstly, two aptamers were synchronously immobilized on the surface of magnetic nanoparticles (MNPs) by coupling with two complementary DNA (cDNA). CEA and AFP specifically recognized the aptamers and then the released cDNA (ssDNA) from the double-strands (dsDNA) triggers NESA, further breaking two detection probes which were labeled with the fluorescent dye (FAM and ROX) and its quencher (BHQ1 and BHQ2) at the same time. Then, the fluorescence signal of FAM and ROX were restored separately. The results indicated that the fluorescence intensity at the emission wavelength of 518 nm and 610 nm had a positive correlation with CEA and AFP concentrations, respectively. Under the optimum conditions, wider liner range of 1–500 ng mL−1 to CEA and 5–800 ng mL−1 to AFP of this fluorescent aptasensor were successfully obtained, achieving a detection limit of CEA and AFP were 0.7 ng mL−1 and 2 ng mL−1, respectively. Hence, it turned out that the aptasensor strategy can be a promising candidate for developing a newly fluorescence assay for the simultaneous quantitative detection of multiple tumor markers in matrix samples by changing the corresponding sequences of aptamer and fluorescent signal probe, which has great potential for the screening of early cancer.

Adsorption of Congo red on magnetic cobalt-manganese ferrite nanoparticles: Adsorption kinetic, isotherm, thermodynamics, and electrochemistry.

Magnetic Co0.5Mn0.5Fe2O4 nanoparticles were successfully prepared via the combustion and calcination process, with an average particle diameter of 31.5 nm and a saturation magnetization of 25.25 emu·g-1, they were employed to adsorbe Congo red (CR) from wastewater, the Pseudo-second-order kinetic and Freundlich isotherm were consistent with the adsorption data, indicating that their adsorption was a multilayer chemisorption process, the thermodynamic investigation showed that the adsorption was a favored exothermic process. The ionic strength of Cl- in CR solution had no obvious effect on the adsorption efficiency of Co0.5Mn0.5Fe2O4 nanoparticles, and the maximum adsorbance was 58.3 mg·g-1 at pH 2, decreasing as the pH of the CR solutions increased from 2 to 12. The ion leaching experiment and XRD demonstrated that Co0.5Mn0.5Fe2O4 nanoparticles had excellent stability, and the relative removal rate was 93.85% of the first time after 7 cycles. Cyclic voltammetry and electrochemical impedance spectroscopy demonstrated that CR was adsorbed onto Co0.5Mn0.5Fe2O4 nanoparticles, and the electrical conductivity of Co0.5Mn0.5Fe2O4 nanoparticles decreased after adsorption of CR. Magnetic Co0.5Mn0.5Fe2O4 nanoparticles displayed a promising application in wastewater treatment.

Construction of a chemiluminescent biosensor based on enzymatic extension and click chemistry for sensitive measurement of MGMT activity in human breast tissues

O6-methylguanine methyltransferase (MGMT) is responsible for dealkylation of naturally occurring O6-methylguanines, and it is closely related with DNA replication, transcription, and cancers. Herein, we develop a chemiluminescent biosensor based on enzymatic extension and click chemistry for sensitive measurement of MGMT activity. When MGMT is present, the MGMT-catalyzed demethylation reaction initiates the cleavage of biotinylated dumbbell probes by PvuII restrictive enzyme, releasing two DNA fragments with 3′-OH end. The resultant DNA fragments can trigger terminal transferase (TdT)- and click chemistry-assisted isothermal amplification to obtain abundant G-rich sequences. The G-rich sequences can be captured by magnetic beads to produce a high chemiluminescence signal. This biosensor can greatly amplify the chemiluminescence signal, facilitating label-free and template-free measurement of MGMT. Especially, the introduction of dumbbell probe and PvuII enzyme can efficiently eliminate the false positive and improve the assay specificity. This biosensor possesses high sensitivity with a detection limit of 1.4 × 10−9 ng/μL, and it may accurately quantify the intracellular MGMT. Importantly, this biosensor can be used to screen the MGMT inhibitors and distinguish the MGMT level in breast tumor tissues and normal tissues, with great potential in drug discovery and cancer diagnosis.

MPS blockade with liposomes controls pharmacokinetics of nanoparticles in a size-dependent manner

Pharmacokinetics of nanomedicines can be improved by a temporal blockade of mononuclear phagocyte system (MPS) through the interaction with other biocompatible nanoparticles. Liposomes are excellent candidates as blocking agents, but the efficiency of the MPS blockade can greatly depend on the liposome properties. Here, we investigated the dependence of the efficiency of the induced MPS blockadein vitroandin vivoon the size of blocking liposomes in the 100-500 nm range. Saturation of RAW 264.7 macrophage uptake was observed for phosphatidylcholine/cholesterol liposomes larger than 200 nmin vitro. In mice, liposomes of all sizes exhibited a blocking effect on liver macrophages, prolonging the circulation of subsequently administrated magnetic nanoparticles in the bloodstream, reducing their liver uptake, and increasing accumulation in the spleen and lungs. Importantly, these effects became more pronounced with the increase of liposome size. Optimization of the size of the blocking liposomes holds the potential to enhance drug delivery and improve cancer therapy.

Investigating the structural and electromagnetic properties of ZnFe2O4@MWCNTs nanocomposites

This study introduces ZnFe2O4@MWCNTs nanocomposites (ZF@MWCNTs NCs), developed using ZnFe2O4 magnetic nanoparticles (ZFNPs) and multi-walled carbon nanotubes (MWCNTs) via a simple, cost-effective, and scalable ultrasonic process. The design involves ZFNPs acting as an electromagnetic (EM) skeleton or magnetic shell surrounding a conductive MWCNT core, optimizing microwave absorption. By combining the magnetic properties of ZFNPs and the electrical conductivity of MWCNTs, the quasi-core-shell structure achieves excellent impedance matching and synergistic dielectric/magnetic loss. Comprehensive characterization was performed, including X-ray diffraction (XRD) for crystal structure, field emission scanning electron microscopy (FESEM) with energy-dispersive X-ray spectroscopy (EDS) for morphology and elemental analysis, Fourier transform infrared (FT-IR) spectroscopy for structural identification, vibrating sample magnetometers (VSM) for magnetic properties, and vector network analyzers (VNA) for dielectric properties. Among the five synthesized weight ratios, M4 sample exhibited the best reflection loss (RL) under the X-band at −47.16 dB with a thickness of 2.33 mm and under the Ku-band at −24.40 dB with a thickness of 1.53 mm. These nanocomposites demonstrated 99.99 % wave dissipation under both X- and Ku-bands, making them highly effective microwave absorbers. This work provides a promising approach for developing high-performance microwave-absorbing materials.

Magnetic Nanoparticles and Radio Frequency Induction: From Specific Heating to Magnetically Induced Catalysis

AbstractThis comprehensive review explores the potential of radio frequency (RF) induction heating in chemical reactions, explicitly focusing on magnetically induced catalysis using magnetic nanoparticles (NPs). We trace the recent historical progress of induction heating and highlight the advancements in liquid and gas‐phase reactions, particularly in its integration with heterogeneous catalysis. The review finds that induction heating profoundly impacts reaction kinetics, and selectivity, and can even reduce overpotentials in electrocatalytic processes. A final outlook unveils the challenges and opportunities associated with aspects such as fundamental research and reactor design, with a particular focus on expanding its use to higher pressures and necessary optimizations to improve energy efficiency. Moreover, it highlights the pressing need for standardized reporting in induction‐heated catalysis. The study underscores the significance of this brand‐new field in developing efficient and sustainable catalytic processes, which are essential for meeting the growing demand for clean energy and sustainable chemical production.

Stiffening of the Cytoplasm in Response to Intracellularly Applied Forces.

Cells constantly encounter mechanical forces that regulate various cellular functions, such as migration, division, and differentiation. Understanding how cells respond to forces at the intracellular level is essential for elucidating the mechanical adaptability of living cells. This study investigates how the cytoplasm alters its mechanical properties in response to forces applied inside a cell. The mechanical properties were measured through in situ characterization using magnetic tweezers to apply mechanical forces on magnetic beads internalized into cells. The findings reveal that the cytoplasm stiffens within seconds when force is applied to the cytoplasm. Macromolecular crowding and cytoskeletal structures, particularly F-actin, were found to significantly contribute to cytoplasm stiffening. The stiffening response was also observed across multiple length scales by using magnetic beads of varying diameters. These results highlight the rapid adaptation of the cytoplasm to mechanical forces applied to the inside of a cell.

Retinol-binding protein 4 is a potential biomarker of changes in lean mass in postmenopausal women.

Identifying biomarkers can help in the early detection of muscle loss and drive the development of new therapies. Research suggests a potential link between retinol-binding protein 4 (RBP4) and muscle mass, particularly in postmenopausal women. This study aimed to examine the association between baseline RBP4 levels and changes in appendicular lean mass (ALM), an indicator of muscle mass, in postmenopausal women. A 12-month follow-up period (n=153) included baseline and 12-month ALM assessments using DXA. ALM was normalized to squared height (ALMI). Baseline evaluations encompassed insulin resistance via HOMA-IR and immunoassay magnetic bead panel measurements of RPB4, IL-6, TNF-α, and IL-10. Postmenopausal women were categorized into higher (n=77) and lower (n=76) RPB4 groups based on baseline RPB4 values. Their changes in ALMI were compared using Mann-Whitney tests. General linear model was employed to evaluate the predictive power of baseline RBP4 for ALMI changes, adjusting for confounding variables: age, physical activity, smoking status, body fat, HOMA-IR, inflammatory markers (TNF-α and IL-6), and anti-inflammatory factor (IL-10). The higher RBP4 group exhibited a more pronounced reduction in ALMI compared to the lower RBP4 group (Higher RBP4 = -0.39kg/m2, 95% CI: -0.48 to -0.31kg/m2vs. Lower RBP4 = -0.24kg/m2, 95% CI: -0.32 to -0.15kg/m2, P=0.011). After adjusting for confounding factors, the association between baseline RBP4 changes and ALMI remained (b = -0.008, SE=0.002, P<0.001), indicating higher baseline RBP4 values linked to greater ALMI reduction. Our findings support RBP4 as a potential biomarker for changes in muscle mass in postmenopausal women.

Plasmonics-enhanced spikey nanorattle-based biosensor for direct SERS detection of mRNA cancer biomarkers.

We present a plasmonics-enhanced spikey nanorattle-based biosensor for direct surface-enhanced Raman scattering (SERS) detection of mRNA cancer biomarkers. Early detection of cancers such as head and neck squamous cell carcinoma (HNSCC) is critical for improving patient outcomes in regions with limited access totraditional diagnostic methods. Our method targets Keratin 14 (KRT14), a promising diagnostic mRNA biomarker for HNSCC, using a sandwich hybridization approach with magnetic beads and SERS spikey nanorattles (SpNR). We synthesized SpNR with a core-gap-shell structure to enhance SERS signals, achieving a limit of detection of 90 femtomolar. A pilot study using clinical samples demonstrated the efficacy of our biosensor in distinguishing between tissue with positive or negative diagnosis for HNSCC, highlighting its potential for rapid and sensitive cancer diagnostics in low-resource settings. This plasmonic assay offers a promising avenue for portable and high-specificity detection of nucleic acid biomarkers, with implications for early cancer detection and improved patient care, especially in middle and low-resource settings.

Inkjet assisted manufacturing of untethered magnetic devices: A comparison between three routes to pattern artificial water striders

AbstractUntethered devices controlled by an external magnetic field are becoming more and more widely used in a wealth of applicative fields: medicine, precise micromanipulation, and environment management. Their production strongly relies on the use of complex and time-consuming technologies typically borrowed from the microelectronic field. In an attempt to reduce costs and enhance manufacturing flexibility, additive manufacturing has been investigated as a relevant alternative for untethered microrobots production. Between the large number of additive manufacturing technologies, inkjet printing is relatively poorly investigated for the production of this kind of devices, and the present work aims at exploring its potential. The work establishes a comparison between different approaches for the inkjet manufacturing of magnetically guidable microdevices. In particular, it focuses on the manufacturing of fully inkjet-printed magnetic devices by proposing two methods of production. The first consists in the electroless metallization of non-magnetic devices printed with SU-8 resin, while the second is based on the inkjet printing of a dispersion of magnetic nanoparticles in SU-8 resin. As a result, inkjet-printed devices controllable by an external magnetic field can be obtained. Multi-step and one-step production methods are compared in terms of quality of the obtained elements, easiness of production, and mechanical properties. The morphology of the finished devices, their surface quality, and their magnetic actuability are analyzed and discussed.

Effect of Magnetic Field and Magnetic Nanoparticles on Choice of Endothelial Cell Phenotype

Background. Endothelial cells as participants in angiogenesis choose their phenotype as tip cells (leading, migratory) or stalk cells (following). It has been experimentally found and theoretically modeled that rapid oscillations in intracellular calcium concentration play a key role in controlling phenotype selection and possible vessel architecture. In addition, the intracellular calcium concentration in endothelial cells is known to be regulated by mechanical wall shear stress induced by blood flow, which controls mechanosensitive calcium ion channel gating. Experimental methods of controlling mechanosensitive ion channel gating in external magnetic fields with application of magnetic nanoparticles are developed that affect magnetic nanoparticles artificially attached to cell membranes. Objective. A key question is raised about the possibility of controlled selection of endothelial cell phenotype in external magnetic fields due to the presence of artificial or biogenic magnetic nanoparticles embedded in the cell membrane. Methods. The magnetic wall shear stress is calculated due to the influence of the external magnetic field on the magnetic nanoparticles embedded in the cell membrane, which controls the mechanosensitive calcium ion pathways. Numerical modeling of oscillations in intracellular calcium concentration in endothelial cells and determination of their final phenotype was carried out taking into account intercellular communication. The python programming language and scipy, py-pde, matplotlib packages of the python programming language were used for numerical modeling. Results. The magnetic field flux density and frequency ranges of a uniform rotating magnetic field, as well as the magnitude of the gradient and the frequency of a non-uniform oscillating magnetic field were calculated for controlling the amplitude and frequency of intracellular calcium concentration oscillations in endothelial cells, as well as the selection of their phenotype. It opens the perspective of controlling angiogenesis and vessel architecture. Conclusions. Phenotype selection by endothelial cells can be controlled in a uniform rotating external magnetic field, as well as in a non-homogeneous oscillating magnetic field.

Drug Delivery Systems for Infectious Eye Diseases: Advancements and Prospects

Infectious ocular diseases like keratitis, conjunctivitis, and endophthalmitis pose significant clinical challenges due to the complexities of delivering drugs to the eye. Recent advancements in drug delivery systems offer promising improvements for treating these conditions. Key strategies include targeted delivery through physicochemical modifications, magnetic nanoparticles, and ligand-receptor interactions. This review explores the safety and biocompatibility of ocular drug delivery systems through in vivo ocular toxicity studies, in vitro cytotoxicity assays, hemocompatibility studies, ocular tolerance tests, and genotoxicity assays. It also examines combination therapies and stimuli-responsive delivery systems for their potential to enhance therapeutic efficacy. Furthermore, we discuss tailored and optimized drug delivery approaches for infectious ocular diseases, outlining current challenges and future directions for developing effective ocular drug delivery systems.

Effect of charge-discharge with higher capacitance performance of Ni-substituted CoFe2O4 magnetic nanoparticles for energy storage

In this work, we synthesized NixCo1-xFe2O4 (0 ≤ x ≤ 0.8) magnetic nanoparticles (MNPs) by using ultrasonication-assisted reverse chemical co-precipitation method. The X-ray diffraction (XRD) patterns confirm the single-phase with mixed spinel structure of the NixCo1-xFe2O4 (0 ≤ x ≤ 0.8) MNPs with the crystallite size range between 12 nm - 17 nm. The molecular dynamics and oleic acid coated Ni-substituted CoFe2O4 magnetic nanoparticles were confirmed by FTIR measurements. The surface composition of NixCo1-xFe2O4 (0 ≤ x ≤ 0.8) MNPs (Ni, Co, Fe and O) and their oxidation states were estimated using X-ray photoelectron spectroscopy. The NixCo1-xFe2O4 (0 ≤ x ≤ 0.8) MNPs are spherical in shape and polycrystalline in nature, confirmed by FESEM and HRTEM measurements. The Ni-substituted CoFe2O4 MNPs with higher zeta potential (ζ) from −24 mV to -41 mV with an increase in Ni concentration, signifies the stable colloidal stability due to the electrostatic repulsion between MNPs. The DC magnetization (M-vs-H) measurements reveal the ferrimagnetic behavior of NixCo1-xFe2O4 (0 ≤ x ≤ 0.8) MNPs, which suppress the saturation magnetization (MS) from 48.6 emu/g to 5.3 emu/g with the enhanced coercivity (HC) from 335 Oe to 1700 Oe with the substitution of Ni2+ ions is in corroboration with electron paramagnetic resonance (EPR) measurements. The enhanced EPR resonance field (Hres = 2335 Oe - 3261 Oe) with the substitution of Ni2+ ions is attributed to the generation of oxygen vacancies and defects, which are predominant in Ni0.8Co0.2Fe2O4, resulting in significantly enhanced electrochemical performance. Therefore, the three-electrode system was utilized to investigate the electrochemical properties of NixCo1-xFe2O4 (0 ≤ x ≤ 0.8) MNPs. The Ni-substituted CoFe2O4 MNPs have demonstrated significantly enhanced capacity retention of 77 % even after 5000 cycles in 1 M H2SO4 electrolyte solution. NixCo1-xFe2O4 (0 ≤ x ≤ 0.8) MNPs exhibit an excellent specific capacity (Cs) of 794.5 F/g at a current density of 1 A/g, signifies the rate of redox reaction at surface electrolyte interface (SEI) is greatly influenced by the surface to volume ratio. Thus, with the enhancement of Ni2+ ions, redox reaction kinetics might become more efficient resulting in the enhanced charge storage capacity.

‘Clickable’ polymer brush coated magnetic nanoparticles: Employing Diels-Alder and azide-alkyne cycloaddition for modular targeted drug delivery platforms

Effective methods of multi-functionalization of nanomaterials are essential for fabricating effective targeted drug delivery systems. Herein, we disclose the fabrication of polymer brush-coated magnetic nanoparticles that could be functionalized with drugs and targeting ligands through orthogonal click reactions. In particular, polymers containing electron-rich furan groups as functionalization handles are grown from the surface of magnetic nanoparticles using the ‘graft-from’ approach. Furthermore, azide groups are installed at the chain end of polymer brushes to furnish an orthogonally functionalizable system. The attachment of maleimide-containing fluorescent dyes and cytotoxic drugs using the Diels-Alder reaction is demonstrated. Drug-conjugated nanoparticles functionalized with integrin-targeting peptide using the azide-alkyne cycloaddition reaction undergo preferential uptake in cancer cells and show dose-dependent cytotoxicity. We envision that the modularly functionalizable system disclosed here could target various cancer cells using an appropriate combination of drugs and targeting groups.

8543 Non-Specific Uptake Of Magnetic Iron Oxide Nanoparticles Into Adrenocortical Carcinoma Cells, Endothelium And Primary Monocytes

Abstract Disclosure: R. Challapalli: None. A. Sorushanova: None. C. Hong: None. N.J. Mullen: None. S. Feely: None. O. Covarrubias-Zambrano: None. J. Covarrubias: None. S. Varghese: None. C. Hantel: None. P. Owens: None. M. O’Halloran: None. P. Prakash: None. S.H. Bossmann: None. M.C. Dennedy: None. Adrenocortical carcinoma (ACC), a rare malignancy with a poor prognosis and a survival rate of up to 24 months, requires varied treatments such as surgery, chemotherapy, or radiation. The high recurrence rate emphasizes the need for innovative therapies. Magnetic iron oxide nanoparticles have emerged as promising candidates for cancer treatment due to their versatility in size and shape and the ability to modify their surface for targeted cellular uptake. In our initial investigation, we assessed the uptake of magnetic iron oxide nanoparticles (IONP) by ACC (H295R, HAC15, and MUC1) cells, HUVECs and primary monocytes, incubated with 0, 5, 10, 20, and 50 µg/ml of IONP for 24 hours. The results demonstrated concentration and time-dependent nanoparticle uptake and its impact on cellular viability. The optimal concentration of IONP was identified as 10 µg/ml, subsequently used to evaluate the rate of uptake and intracellular location. The efficiency of IONP uptake by ACC cells decreased when exposed to primary monocytes and an HUVEC layer, as demonstrated through a Transwell migration system. This study revealed insights into the non-specific uptake of IONP by ACC, primarily attributed to the mechanism of macropinocytosis. These preliminary findings lay the groundwork for exploring potential modifications to enhance specific uptake by ACC cells, particularly for applications like magnet-induced thermal ablation or nanobiocontrast. Presentation: 6/2/2024