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Proof of concept of plasmonic thermal destruction of surface cancers by gold nanoparticles obtained by green chemistry
摘要: A greener approach for the design of surface plasmon resonant gold nanoparticles has been obtained with a hydrosoluble fraction of an endemic asteraceae medicinal plant. This medicinal plant is originated from Indian Ocean and demonstrates its bioreducing activity in the design of stable green nanomedicine in aqueous media. This article describes the preclinical assessment of the efficacy of these novel nanocandidates on murine model by intratumoral and intravenous injections. It definitely demonstrates two key points in the treatment of cancer: 1) optimization of the tumor microenvironment targeting by specific ligands for a limited damage on healthy tissue, 2) the need to screen the specific irradiation dose (time, power) taking into account the type of tumor.
关键词: Medicinal plant,Hyperthermia,Green nanomedicine,Plasmonic photothermal therapy,Gold nanoparticle
更新于2025-11-14 15:25:21
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Optical and Magnetic Properties of Cobalt Ions Doped Calcium Phosphate by Ultrasonication
摘要: Background: Hydroxyapatite (HAp) is a remarkable member of the calcium phosphate family. It resembles natural bone in both structure and chemical composition. Owing to its bioactive and chemical properties, it has been used as a biocompatible osteogenesis and energy materials as discussed in patents. Objective: To study the structural, optical properties and magnetic properties of hydroxyapatite and cobalt ions doped hydroxyapatite for biomedical application. Method: Hydroxyapatite and cobalt ions doped hydroxyapatite were synthesized by ultrasonication assisted wet chemical synthesis. Results: X-ray diffraction analysis confirmed the phase and crystallite size of hydroxyapatite. There was a 12% decrease in crystallite size compared to pristine. The functional groups and vibrational assignments of the samples were observed in infra-red and Raman spectra. Optical properties of the samples were analyzed by Diffuse Reflectance Spectroscopy, ultraviolet-visible and photoluminescence emission spectroscopy. Doped samples showed paramagnetic in nature. Conclusion: Therefore, the cobalt doped samples could be employed in biomedical applications.
关键词: optical,luminescence,hyperthermia,bioceramics,Cobalt ions,magnetic,hydroxyapatite
更新于2025-09-23 15:23:52
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Bi-functional heater-thermometer Nd3+-doped nanoparticles with multiple temperature sensing parameters
摘要: Achieving a combination of real-time diagnosis and therapy in a single platform with sensitive thermometry and efficient heat production is a crucial step towards controllable photo-thermal therapy. Here, Nd3+-doped Y2O3 nanoparticles prepared by combined Pechini-foaming technique operating in first and second biological windows were demonstrated as thermal sensors within wide temperature range of 123–873 K and heaters with temperature increase by 100 K. Thermal sensing was performed based on various approaches: luminescence intensity ratio (electronic levels; Stark sublevels), spectral line position and line bandwidth were used as temperature dependent parameters. Applicability of regarded sensing parameters along with relative thermal sensitivity and temperature resolution were discussed and compared. Influence of Nd3+ doping concentration on thermometer and heater efficiency was also investigated.
关键词: Nanosensor,Biological window,Hyperthermia,Luminescence,Thermometry,Nd3+
更新于2025-09-23 15:23:52
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[IEEE 2019 PhotonIcs & Electromagnetics Research Symposium - Spring (PIERS-Spring) - Rome, Italy (2019.6.17-2019.6.20)] 2019 PhotonIcs & Electromagnetics Research Symposium - Spring (PIERS-Spring) - Design and Implementation of Fiber-embedded Plasmonic Structures in Microwires
摘要: General principles are developed using a finite element model regarding how time-dependent power dissipation of magnetic nanoparticles can be used to optimize hyperthermia selectivity. To make the simulation more realistic, the finite size and spatial location of each individual nanoparticle is taken into consideration. When energy input into the system and duration of treatment is held constant, increasing the maximum power dissipation of nanoparticles increases concentrations of energy in the tumor. Furthermore, when the power dissipation of magnetic nanoparticles rises linearly, the temperature gradient on the edge of the tumor increases exponentially. With energy input held constant, the location and duration of maximum power dissipation in the treatment time scheme will affect the final energy concentration inside the tumor. Finally, connections are made between the simulation results and optimization of the design of nanoparticle power dissipation time-schemes for hyperthermia.
关键词: treatment planning,finite-element modeling,Hyperthermia optimization,magnetic nanoparticles
更新于2025-09-23 15:21:01
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Local Overheating of Biotissue Labeled With Upconversion Nanoparticles Under Yb3+ Resonance Excitation
摘要: Local overheating of biotissue is a critical step for biomedical applications, such as photothermal therapy, enhancement of vascular permeability, remote control of drug release, and so on. Overheating of biological tissue when exposed to light is usually realized by utilizing the materials with a high-absorption cross section (gold, silica, carbon nanoparticles, etc.). Here, we demonstrate core/shell NaYF4:Yb3+, Tm3+/NaYF4 upconversion nanoparticles (UCNPs) commonly used for bioimaging as promising near-infrared (NIR) absorbers for local overheating of biotissue. We assume that achievable temperature of tissue labeled with nanoparticles is high enough because of Yb3+ resonance absorption of NIR radiation, whereas the use of auxiliary light-absorbing materials or shells is optional for photothermal therapy. For this purpose, a computational model of tissue heating based on the energy balance equations was developed and verified with the experimentally obtained thermal-graphic maps of a mouse in response to the 975-nm laser irradiation. Labeling of biotissue with UCNPs was found to increase the local temperature up to 2?C compared to that of the non-labeled area under the laser intensity lower than 1 W/cm2. The cellular response to the UCNP-initiated hyperthermia at subcritical ablation temperatures (lower than 42?C) was demonstrated by measuring the heat shock protein overexpression. This indicates that the absorption cross section of Yb3+ in UCNPs is relatively large, and microscopic temperature of nanoparticles exceeds the integral tissue temperature. In summary, a new approach based on the use of UCNP without any additional NIR absorbers was used to demonstrate a simple approach in the development of photoluminescent probes for simultaneous bioimaging and local hyperthermia.
关键词: near-infrared irradiation,local overheating,photothermal material,bioimaging,heat shock proteins,biotissue laser heating,hyperthermia,upconversion nanoparticles
更新于2025-09-23 15:21:01
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Biocompatible superparamagnetic core-shell nanoparticles for potential use in hyperthermia-enabled drug release and as an enhanced contrast agent
摘要: Superparamagnetic iron oxide nanoparticles (SPIONs) and core-shell type nanoparticles, consisting of SPIONs coated with mesoporous silica and/or lipid, were synthesized and tested for their potential theranostic applications in drug delivery, magnetic hyperthermia and as a contrast agent. Transmission Electron Microscopy (TEM) confirmed the size of bare and coated SPIONs was in the range of 5-20 nm and 100-200 nm respectively. The superparamagnetic nature of all the prepared nanomaterials as indicated by Vibrating Sample Magnetometry (VSM) and their heating properties under an AC field confirm their potential for hyperthermia applications. Scanning Column Magnetometry (SCM) data showed that extrusion of bare-SPION (b-SPION) dispersions through a 100 nm polycarbonate membrane significantly improved the dispersion stability of the sample. No sedimentation was apparent after 18 hours compared to a pre-extrusion estimate of 43% settled at the bottom of the tube over the same time. Lipid coating also enhanced dispersion stability. Transversal relaxation time (T2) measurements for the nanoparticles, using a bench-top relaxometer, displayed a significantly lower value of 46 ms, with a narrow relaxation time distribution, for lipid silica coated SPIONs (Lip-SiSPIONs) as compared to that of 1316 ms for the b-SPIONs. Entrapment efficiency of the anticancer drug, Doxorubicin (DOX) for Lip-SPIONs was observed to be 35% which increased to 58% for Lip-SiSPIONs. Moreover, initial in-vitro cytotoxicity studies against human breast adenocarcinoma, MCF-7 cells showed that % cell viability increased from 57% for bSPIONs to 82% for Lip-SPIONs and to 87% for Lip-SiSPIONs. This suggests that silica and lipid coatings improve the biocompatibility of bSPIONs significantly and enhance the suitability of these particles as drug carriers. Hence, the magnetic nanomaterials prepared in this work have potential theranostic properties as a drug carrier for hyperthermia cancer therapy and also offer enhancement of contrast agent efficacy and a route to a significant increase in dispersion stability.
关键词: magnetoliposomes,drug carrier,cancer therapy,colloidal stability,hyperthermia,theranostic,Superparamagnetic iron oxide nanoparticles
更新于2025-09-23 15:21:01
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Ultrafast pulse generation for Er- and Tm- doped fiber lasers with Sb thin film saturable absorber
摘要: General principles are developed using a finite element model regarding how time-dependent power dissipation of magnetic nanoparticles can be used to optimize hyperthermia selectivity. To make the simulation more realistic, the finite size and spatial location of each individual nanoparticle is taken into consideration. When energy input into the system and duration of treatment is held constant, increasing the maximum power dissipation of nanoparticles increases concentrations of energy in the tumor. Furthermore, when the power dissipation of magnetic nanoparticles rises linearly, the temperature gradient on the edge of the tumor increases exponentially. With energy input held constant, the location and duration of maximum power dissipation in the treatment time scheme will affect the final energy concentration inside the tumor. Finally, connections are made between the simulation results and optimization of the design of nanoparticle power dissipation time-schemes for hyperthermia.
关键词: treatment planning,finite-element modeling,Hyperthermia optimization,magnetic nanoparticles
更新于2025-09-23 15:19:57
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Single-Cell ATP Content Monitoring during Hyperthermia Cell Death by using Plasmonic Fluorescent Nanoflare
摘要: Gold nanorods-based plasmonic photothermal therapy (AuNRs-PPTT) has been a prospective anti-cancer approach in which AuNRs absorbs near-infrared (NIR) light and converts it into heat, leading to cell death. Investigating molecular energy metabolism of single cells, especially cancer cells, during hyperthermia cell death process is therefore of great significance, as it can help us to better understand the photothermal lethal mechanism of cancer cells and design new photothermal probes more rationally. However, during the AuNRs-PPTT process, how the cells respond to heat stimulation, and how their energy metabolism changes, these basic issues have rarely been studied. Herein, we selected adenosine triphosphate (ATP) as a target molecule, and by preparing a plasmonic and turn-on type fluorescent nanoprobe we examined the ATP metabolism difference between cancerous cells and normal cells during the AuNRs-PPTT process. We found that the fluorescence intensity increased ~ 60% after 5 min laser irradiation as compared to the initial intensity in single HeLa cells, but only ~ 20% increasement was observed for single H8 cells; obviously the increase of ATP content in cancerous cells was notably higher than that in normal cells during the hyperthermia cell death.
关键词: Plasmonic photothermal therapy,Fluorescent nanoprobe,ATP,Gold nanorods,Hyperthermia cell death
更新于2025-09-19 17:13:59
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All-in-one theranostic nanoplatform with controlled drug release and activated MRI tracking functions for synergistic NIR-II hyperthermia-chemotherapy of tumors
摘要: Real-time tracking drug release behavior is fundamentally important for avoiding adverse effects or unsuccessful treatment in personalize medical treatment. However, the development of a non-invasive drug reporting platform still remains challenging. Herein the design of a novel synthetic magnetic resonance imaging (MRI) agent for drug release tracking (SMART) is reported, which integrates photothermal core and paramagnetic ion/drug loading shell with a thermal valve in a hybrid structure. Through near-infrared (NIR)-II photothermal effect originating from inner Au-Cu9S5 nanohybrid core, burst release of drugs loaded in the mesoporous silica shell is achieved. The concomitant use of a phase change material not only prevents premature drug release, but also regulates heating effect, keeping local temperature below 45 oC, enabling synergistic chemotherapy and mild hyperthermia in vitro and in vivo. Furthermore, the drug release from SMART facilitates proton accessibility to the paramagnetic ions anchored inside mesopores channels, enhancing longitudinal T1 relaxation rate and displaying positive signal correlation to the amount of released drug, thus allowing non-invasive real-time monitoring of drug release event. The current study highlights the potential of designed MRI nanophores such as SMART for real-time and in-situ monitoring of drug delivery for precision theranostic applications.
关键词: drug delivery,chemotherapy,NIR-II window,magnetic resonance,hyperthermia
更新于2025-09-19 17:13:59
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Synergistical Use of Electrostatic and Hydrophobic Interactions for the Synthesis of a New Class of Multifunctional Nanohybrids: Plasmonic Magneto-Liposomes
摘要: By carefully controlling the electrostatic interactions between cationic liposomes, which already incorporate magnetic nanoparticles in the bilayers, and anionic gold nanoparticles, a new class of versatile multifunctional nanohybrids (plasmonic magneto-liposomes) that could have a major impact in drug delivery and controlled release applications has been synthesized. The experimental results confirmed the successful synthesis of hydrophobic superparamagnetic iron oxide nanoparticles (SPIONs) and polyethylene glycol functionalized (PEGylated) gold nanoparticles (AuNPs). The SPIONs were incorporated in the liposomal lipidic bilayers, thus promoting the formation of cationic magnetoliposomes. Different concentrations of SPIONs were loaded in the membrane. The cationic magnetoliposomes were decorated with anionic PEGylated gold nanoparticles using electrostatic interactions. The successful incorporation of SPIONs together with the modifications they generate in the bilayer were analyzed using Raman spectroscopy. The plasmonic properties of the multifunctional nanohybrids were investigated using UV-Vis absorption and (surface-enhanced) Raman spectroscopy. Their hyperthermic properties were recorded at different frequencies and magnetic field intensities. After the synthesis, the nanosystems were extensively characterized in order to properly evaluate their potential use in drug delivery applications and controlled release as a result of the interaction with an external stimulus, such as an NIR laser or alternating magnetic field.
关键词: superparamagnetic nanoparticles,hyperthermia,multifunctional nanohybrids,gold nanoparticles,magneto-liposomes
更新于2025-09-16 10:30:52