Your search keyword '"Kabashin AV"' showing total 8 results

1. Laser-ablative aqueous synthesis and characterization of elemental boron nanoparticles for biomedical applications.

Author

Pastukhov AI, Belyaev IB, Bulmahn JC, Zelepukin IV, Popov AA, Zavestovskaya IN, Klimentov SM, Deyev SM, Prasad PN, and Kabashin AV

Subjects

Cell Line, Tumor, Lasers, Water chemistry, Boron, Nanoparticles chemistry

Abstract

Boron-based nano-formulations look very promising for biomedical applications, including photo- and boron neutron capture therapies, but the fabrication of non-toxic water-dispersible boron nanoparticles (NPs), which contain the highest boron atom concentration, is difficult using currently available chemical and plasma synthesis methods. Here, we demonstrate purely aqueous synthesis of clean boron NPs by methods of femtosecond laser ablation from a solid boron target in water, thus free of any toxic organic solvents, and characterize their properties. We show that despite highly oxidizing water ambience, the laser-ablative synthesis process follows an unusual scenario leading to the formation of boron NPs together with boric acid (H 3 BO 3 ) as an oxidation by-product coating the nanoparticles, which acts to stabilize the elemental boron NPs dispersion. We then demonstrate the purification of boron NPs from residual boric acid in deionized water, followed by their coating with polyethylene glycol to improve colloidal stability and biocompatibility. It was found that the formed NPs have a spherical shape with averaged size of about 37 nm, and are composed of elemental boron in mostly amorphous phase with the presence of certain crystalline fraction. The synthesized NPs demonstrate low toxicity and exhibit strong absorption in the NIR window of relative tissue transparency, promising their use in photoacoustic imaging and phototherapy, in addition to their promise for neutron capture therapy. This combined potential ability of generating imaging and therapy functionalities makes laser-synthesized B NPs a very promising multifunctional agent for biomedical applications., (© 2022. The Author(s).)

Published

2022

2. In vivo evaluation of safety, biodistribution and pharmacokinetics of laser-synthesized gold nanoparticles.

Author

Bailly AL, Correard F, Popov A, Tselikov G, Chaspoul F, Appay R, Al-Kattan A, Kabashin AV, Braguer D, and Esteve MA

Subjects

Animals, Body Weight drug effects, Dextrans chemistry, Female, Gold chemistry, Intracellular Space drug effects, Intracellular Space metabolism, Rats, Tissue Distribution, Gold adverse effects, Gold pharmacokinetics, Lasers, Metal Nanoparticles chemistry, Safety

Abstract

Capable of generating plasmonic and other effects, gold nanostructures can offer a variety of diagnostic and therapy functionalities for biomedical applications, but conventional chemically-synthesized Au nanomaterials cannot always match stringent requirements for toxicity levels and surface conditioning. Laser-synthesized Au nanoparticles (AuNP) present a viable alternative to chemical counterparts and can offer exceptional purity (no trace of contaminants) and unusual surface chemistry making possible direct conjugation with biocompatible polymers (dextran, polyethylene glycol). This work presents the first pharmacokinetics, biodistribution and safety study of laser-ablated dextran-coated AuNP (AuNPd) under intravenous administration in small animal model. Our data show that AuNPd are rapidly eliminated from the blood circulation and accumulated preferentially in liver and spleen, without inducing liver or kidney toxicity, as confirmed by the plasmatic ALAT and ASAT activities, and creatininemia values. Despite certain residual accumulation in tissues, we did not detect any sign of histological damage or inflammation in tissues, while IL-6 level confirmed the absence of any chronic inflammation. The safety of AuNPd was confirmed by healthy behavior of animals and the absence of acute and chronic toxicities in liver, spleen and kidneys. Our results demonstrate that laser-synthesized AuNP are safe for biological systems, which promises their successful biomedical applications.

Published

2019

3. Nuclear nanomedicine using Si nanoparticles as safe and effective carriers of 188 Re radionuclide for cancer therapy.

Author

Petriev VM, Tischenko VK, Mikhailovskaya AA, Popov AA, Tselikov G, Zelepukin I, Deyev SM, Kaprin AD, Ivanov S, Timoshenko VY, Prasad PN, Zavestovskaya IN, and Kabashin AV

Subjects

Cell Line, Tumor, Humans, Nuclear Medicine, Polyethylene Glycols chemistry, Radioisotopes pharmacokinetics, Rhenium pharmacokinetics, Tissue Distribution, Drug Carriers chemistry, Nanomedicine, Nanoparticles chemistry, Radioisotopes chemistry, Radioisotopes therapeutic use, Rhenium chemistry, Rhenium therapeutic use, Safety, Silicon chemistry

Abstract

Nuclear nanomedicine, with its targeting ability and heavily loading capacity, along with its enhanced retention to avoid rapid clearance as faced with molecular radiopharmaceuticals, provides unique opportunities to treat tumors and metastasis. Despite these promises, this field has seen limited activities, primarily because of a lack of suitable nanocarriers, which are safe, excretable and have favorable pharmacokinetics to efficiently deliver and retain radionuclides in a tumor. Here, we introduce biodegradable laser-synthesized Si nanoparticles having round shape, controllable low-dispersion size, and being free of any toxic impurities, as highly suitable carriers of therapeutic 188 Re radionuclide. The conjugation of the polyethylene glycol-coated Si nanoparticles with radioactive 188 Re takes merely 1 hour, compared to its half-life of 17 hours. When intravenously administered in a Wistar rat model, the conjugates demonstrate free circulation in the blood stream to reach all organs and target tumors, which is radically in contrast with that of the 188 Re salt that mostly accumulates in the thyroid gland. We also show that the nanoparticles ensure excellent retention of 188 Re in tumor, not possible with the salt, which enables one to maximize the therapeutic effect, as well as exhibit a complete time-delayed conjugate bioelimination. Finally, our tests on rat survival demonstrate excellent therapeutic effect (72% survival compared to 0% of the control group). Combined with a series of imaging and therapeutic functionalities based on unique intrinsic properties of Si nanoparticles, the proposed biodegradable complex promises a major advancement in nuclear nanomedicine.

Published

2019

4. Laser- synthesized TiN nanoparticles as promising plasmonic alternative for biomedical applications.

Author

Popov AA, Tselikov G, Dumas N, Berard C, Metwally K, Jones N, Al-Kattan A, Larrat B, Braguer D, Mensah S, Da Silva A, Estève MA, and Kabashin AV

Abstract

Exhibiting a red-shifted absorption/scattering feature compared to conventional plasmonic metals, titanium nitride nanoparticles (TiN NPs) look as very promising candidates for biomedical applications, but these applications are still underexplored despite the presence of extensive data for conventional plasmonic counterparts. Here, we report the fabrication of ultrapure, size-tunable TiN NPs by methods of femtosecond laser ablation in liquids and their biological testing. We show that TiN NPs demonstrate strong and broad plasmonic peak around 640-700 nm with a significant tail over 800 nm even for small NPs sizes (<7 nm). In vitro tests of laser-synthesized TiN NPs on cellular models evidence their low cytotoxicity and excellent cell uptake. We finally demonstrate a strong photothermal therapy effect on U87-MG cancer cell cultures using TiN NPs as sensitizers of local hyperthermia under near-infrared laser excitation. Based on absorption band in the region of relative tissue transparency and acceptable biocompatibility, laser-synthesized TiN NPs promise the advancement of biomedical modalities employing plasmonic effects, including absorption/scattering contrast imaging, photothermal therapy, photoacoustic imaging and SERS.

Published

2019

5. Ultrapure laser-synthesized Si-based nanomaterials for biomedical applications: in vivo assessment of safety and biodistribution.

Author

Baati T, Al-Kattan A, Esteve MA, Njim L, Ryabchikov Y, Chaspoul F, Hammami M, Sentis M, Kabashin AV, and Braguer D

Subjects

Administration, Intravenous, Animals, Liver chemistry, Mice, Nanomedicine methods, Nanostructures adverse effects, Silicon adverse effects, Spleen chemistry, Trace Elements adverse effects, Urine chemistry, Biological Availability, Lasers, Nanostructures administration & dosage, Silicon administration & dosage, Silicon pharmacokinetics, Trace Elements administration & dosage, Trace Elements pharmacokinetics

Abstract

Si/SiOx nanoparticles (NPs) produced by laser ablation in deionized water or aqueous biocompatible solutions present a novel extremely promising object for biomedical applications, but the interaction of these NPs with biological systems has not yet been systematically examined. Here, we present the first comprehensive study of biodistribution, biodegradability and toxicity of laser-synthesized Si-SiOx nanoparticles using a small animal model. Despite a relatively high dose of Si-NPs (20 mg/kg) administered intravenously in mice, all controlled parameters (serum, enzymatic, histological etc.) were found to be within safe limits 3 h, 24 h, 48 h and 7 days after the administration. We also determined that the nanoparticles are rapidly sequestered by the liver and spleen, then further biodegraded and directly eliminated in urine without any toxicity effects. Finally, we found that intracellular accumulation of Si-NPs does not induce any oxidative stress damage. Our results evidence a huge potential in using these safe and biodegradable NPs in biomedical applications, in particular as vectors, contrast agents and sensitizers in cancer therapy and diagnostics (theranostics).

Published

2016

6. 3D plasmonic crystal metamaterials for ultra-sensitive biosensing.

Author

Aristov AI, Manousidaki M, Danilov A, Terzaki K, Fotakis C, Farsari M, and Kabashin AV

Subjects

Biosensing Techniques methods

Abstract

We explore the excitation of plasmons in 3D plasmon crystal metamaterials and report the observation of a delocalized plasmon mode, which provides extremely high spectral sensitivity (>2600 nm per refractive index unit (RIU) change), outperforming all plasmonic counterparts excited in 2D nanoscale geometries, as well as a prominent phase-sensitive response (>3*10(4) deg. of phase per RIU). Combined with a large surface for bioimmobilization provided by the 3D matrix, the proposed sensor architecture promises a new important landmark in the advancement of plasmonic biosensing technology.

Published

2016

7. Laser-synthesized oxide-passivated bright Si quantum dots for bioimaging.

Author

Gongalsky MB, Osminkina LA, Pereira A, Manankov AA, Fedorenko AA, Vasiliev AN, Solovyev VV, Kudryavtsev AA, Sentis M, Kabashin AV, and Timoshenko VY

Subjects

Cell Line, Tumor, Humans, Lasers, Silicon, Contrast Media chemistry, Luminescent Measurements, Optical Imaging methods, Quantum Dots chemistry

Abstract

Crystalline silicon (Si) nanoparticles present an extremely promising object for bioimaging based on photoluminescence (PL) in the visible and near-infrared spectral regions, but their efficient PL emission in aqueous suspension is typically observed after wet chemistry procedures leading to residual toxicity issues. Here, we introduce ultrapure laser-synthesized Si-based quantum dots (QDs), which are water-dispersible and exhibit bright exciton PL in the window of relative tissue transparency near 800 nm. Based on the laser ablation of crystalline Si targets in gaseous helium, followed by ultrasound-assisted dispersion of the deposited films in physiological saline, the proposed method avoids any toxic by-products during the synthesis. We demonstrate efficient contrast of the Si QDs in living cells by following the exciton PL. We also show that the prepared QDs do not provoke any cytoxicity effects while penetrating into the cells and efficiently accumulating near the cell membrane and in the cytoplasm. Combined with the possibility of enabling parallel therapeutic channels, ultrapure laser-synthesized Si nanostructures present unique object for cancer theranostic applications.

Published

2016

8. Radio frequency radiation-induced hyperthermia using Si nanoparticle-based sensitizers for mild cancer therapy.

Author

Tamarov KP, Osminkina LA, Zinovyev SV, Maximova KA, Kargina JV, Gongalsky MB, Ryabchikov Y, Al-Kattan A, Sviridov AP, Sentis M, Ivanov AV, Nikiforov VN, Kabashin AV, and Timoshenko VY

Subjects

Animals, Carcinoma, Lewis Lung pathology, Catheter Ablation instrumentation, Crystallization, Hindlimb, Hyperthermia, Induced instrumentation, Injections, Intralesional, Lasers, Male, Mice, Mice, Inbred CBA, Nanoparticles chemistry, Neoplasm Transplantation, Porosity, Temperature, Carcinoma, Lewis Lung therapy, Catheter Ablation methods, Hyperthermia, Induced methods, Nanoparticles administration & dosage, Silicon chemistry

Abstract

Offering mild, non-invasive and deep cancer therapy modality, radio frequency (RF) radiation-induced hyperthermia lacks for efficient biodegradable RF sensitizers to selectively target cancer cells and thus avoid side effects. Here, we assess crystalline silicon (Si) based nanomaterials as sensitizers for the RF-induced therapy. Using nanoparticles produced by mechanical grinding of porous silicon and ultraclean laser-ablative synthesis, we report efficient RF-induced heating of aqueous suspensions of the nanoparticles to temperatures above 45-50 °C under relatively low nanoparticle concentrations (<1 mg/mL) and RF radiation intensities (1-5 W/cm(2)). For both types of nanoparticles the heating rate was linearly dependent on nanoparticle concentration, while laser-ablated nanoparticles demonstrated a remarkably higher heating rate than porous silicon-based ones for the whole range of the used concentrations from 0.01 to 0.4 mg/mL. The observed effect is explained by the Joule heating due to the generation of electrical currents at the nanoparticle/water interface. Profiting from the nanoparticle-based hyperthermia, we demonstrate an efficient treatment of Lewis lung carcinoma in vivo. Combined with the possibility of involvement of parallel imaging and treatment channels based on unique optical properties of Si-based nanomaterials, the proposed method promises a new landmark in the development of new modalities for mild cancer therapy.

Published

2014