Near Infrared Light-Powered Janus Mesoporous Silica Nanoparticle Motors

Xuan, Mingjun; Wu, Zhiguang; Shao, Jianzhong; Dai, Luru; Si, Tieyan; He, Qiang

doi:10.1021/jacs.6b00902

Cited by 416 publications

(355 citation statements)

References 57 publications

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“…To prepare this nanocarrier, the RBC membranes were freshly harvested and physically extruded into vesicles by using ap revious method (Supporting Information, Figure S1). [41] Themesoporous pore structure of MSNs was visually characterized by transmission electron microscopy (TEM), and displayed an payload property to delivery guest molecules ( Figure 1B). [41] Themesoporous pore structure of MSNs was visually characterized by transmission electron microscopy (TEM), and displayed an payload property to delivery guest molecules ( Figure 1B).…”

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Magnetic Mesoporous Silica Nanoparticles Cloaked by Red Blood Cell Membranes: Applications in Cancer Therapy

et al. 2018

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Targeted drug delivery is an emerging technological strategy that enables nanoparticle systems to be responsive for tumor therapy. Magnetic mesoporous silica nanoparticles (MMSNs) were cloaked with red blood cell membrane (RBC). This integrates long circulation, photosensitizer delivery, and magnetic targeting for cancer therapy. In vivo experiments demonstrate that RBC@MMSNs can avoid immune clearance and achieve magnetic field (MF)-induced high accumulation in a tumor. When light irradiation is applied, singlet oxygen rapidly generates from hypocrellin B (HB)-loaded RBC@MMSN and leads to the necrosis of tumor tissue. Such a RBC-cloaked magnetic nanocarrier effectively integrates immunological adjuvant, photosensitizer delivery, MF-assisted targeting photodynamic therapy, which provides an innovative strategy for cancer therapy.

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Magnetic Mesoporous Silica Nanoparticles Cloaked by Red Blood Cell Membranes: Applications in Cancer Therapy

et al. 2018

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“…1−9 Until now, many examples of different types of motors (micro- and nanotubes, 10−12 wires, 13,14 helices, 15,16 rods, 17−19 Janus motors 20−23 and self-assembled polymeric motors 24−28 ) have been developed. These artificial motors are capable of converting chemical or external energy into autonomous movement and possess various potential applications such as environmental remediation, sensing, and drug delivery.…”

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Biodegradable Hybrid Stomatocyte Nanomotors for Drug Delivery

et al. 2017

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We report the self-assembly of a biodegradable platinum nanoparticle-loaded stomatocyte nanomotor containing both PEG-b-PCL and PEG-b-PS as a potential candidate for anticancer drug delivery. Well-defined stomatocyte structures could be formed even after incorporation of 50% PEG-b-PCL polymer. Demixing of the two polymers was expected at high percentage of semicrystalline poly(ε-caprolactone) (PCL), resulting in PCL domain formation onto the membrane due to different properties of two polymers. The biodegradable motor system was further shown to move directionally with speeds up to 39 μm/s by converting chemical fuel, hydrogen peroxide, into mechanical motion as well as rapidly delivering the drug to the targeted cancer cell. Uptake by cancer cells and fast doxorubicin drug release was demonstrated during the degradation of the motor system. Such biodegradable nanomotors provide a convenient and efficient platform for the delivery and controlled release of therapeutic drugs.

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“…[4] Light is an extremely attractive stimulus for controlling the motion of synthetic nanomotors for numerous reasons.F irst, light is ar emote non-invasive external trigger and could easily modulate chemical processes upon interaction with photo-responsive materials.Inaddition, different light intensities and wavelengths open the door to am ultitude of materials,d esigns,a nd media. [6] However, slowing and halting the motion of chemically powered motors using light as stimulus has been very challenging. [6] However, slowing and halting the motion of chemically powered motors using light as stimulus has been very challenging.…”

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Chemical/Light‐Powered Hybrid Micromotors with “On‐the‐Fly” Optical Brakes

et al. 2018

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Hybrid micromotors capable of both chemically powered propulsion and fuel-free light-driven actuation and offering built-in optical brakes for chemical propulsion are described. The new hybrid micromotors are designed by combining photocatalytic TiO 2 and catalytic Pt surfaces into aJ anus microparticle.T he chemical reactions on the different surfaces of the Janus particle hybrid micromotor can be tailored by using chemical or light stimuli that generate counteracting propulsion forces on the catalytic Pt and photocatalytic TiO 2 sides.Such modulation of the surface chemistry on as ingle micromotor leads to switchable propulsion modes and reversal of the direction of motion that reflect the tuning of the local ion concentration and hence the dominant propulsion force.Anintermediate Au layer (under the Pt surface) plays an important role in determining the propulsion mechanism and operation of the hybrid motor.T he built-in optical braking system allows "on-the-fly" control of the chemical propulsion through aphotocatalytic reaction on the TiO 2 side to counterbalance the chemical propulsion force generated on the Pt side. The adaptive dual operation of these chemical/light hybrid micromotors,a ssociated with such control of the surface chemistry,h olds considerable promise for designing smart nanomachines that autonomously reconfigure their propulsion mode for various on-demand operations.

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Near Infrared Light-Powered Janus Mesoporous Silica Nanoparticle Motors

Cited by 416 publications

References 57 publications

Magnetic Mesoporous Silica Nanoparticles Cloaked by Red Blood Cell Membranes: Applications in Cancer Therapy

Magnetic Mesoporous Silica Nanoparticles Cloaked by Red Blood Cell Membranes: Applications in Cancer Therapy

Biodegradable Hybrid Stomatocyte Nanomotors for Drug Delivery

Chemical/Light‐Powered Hybrid Micromotors with “On‐the‐Fly” Optical Brakes

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