Zhiqin Chu scite author profile

Cellular fate of nanoparticles is vital to application of nanoparticles to cell imaging, bio-sensing, drug delivery, suppression of drug resistance, gene delivery, and cytotoxicity analysis. However, the current studies on cellular fate of nanoparticles have been controversial due to complications of interplay between many possible factors. By well-controlled experiments, we demonstrated unambiguously that the morphology of nanoparticles independently determined their cellular fate. We found that nanoparticles with sharp shapes, regardless of their surface chemistry, size, or composition, could pierce the membranes of endosomes that carried them into the cells and escape to the cytoplasm, which in turn significantly reduced the cellular excretion rate of the nanoparticles. Such features of sharp-shaped nanoparticles are essential for drug delivery, gene delivery, subcellular targeting, and long-term tracking. This work opens up a controllable, purely geometrical and hence safe, degree of freedom for manipulating nanoparticle-cell interaction, with numerous applications in medicine, bio-imaging, and bio-sensing.

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Controllable Drug Release and Simultaneously Carrier Decomposition of SiO₂-Drug Composite Nanoparticles

Zhang

et al. 2013

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Drug release simultaneously with carrier decomposition has been demonstrated in SiO2-drug composite nanoparticles. By creating a radial drug concentration gradient in the nanoparticle, controllable release of the drug is primarily driven by diffusion. Escape of the drug molecules then triggers the SiO2 carrier decomposition, which starts from the center of the nanoparticle and eventually leads to its complete fragmentation. The small size of the final carrier fragments enables their easy excretion via renal systems. Together with the known biocompatibility of SiO2, the feature of controllable drug release and simultaneous carrier decomposition achieved in the SiO2-drug nanoparticles make it ideal for a wide range of diagnostic and therapeutic applications with great promise for potential clinical translation.

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Optical imaging of localized chemical events using programmable diamond quantum nanosensors

et al. 2017

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Development of multifunctional nanoscale sensors working under physiological conditions enables monitoring of intracellular processes that are important for various biological and medical applications. By attaching paramagnetic gadolinium complexes to nanodiamonds (NDs) with nitrogen-vacancy (NV) centres through surface engineering, we developed a hybrid nanoscale sensor that can be adjusted to directly monitor physiological species through a proposed sensing scheme based on NV spin relaxometry. We adopt a single-step method to measure spin relaxation rates enabling time-dependent measurements on changes in pH or redox potential at a submicrometre-length scale in a microfluidic channel that mimics cellular environments. Our experimental data are reproduced by numerical simulations of the NV spin interaction with gadolinium complexes covering the NDs. Considering the versatile engineering options provided by polymer chemistry, the underlying mechanism can be expanded to detect a variety of physiologically relevant species and variables.

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Surface Roughness and Substrate Stiffness Synergize To Drive Cellular Mechanoresponse

et al. 2019

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Material surface topographic features have been shown to be crucial for tissue regeneration and surface treatment of implanted devices. Many biomaterials were investigated with respect to the response of cells on surface roughness. However, some conclusions even conflicted with each other due to the unclear interplay of surface topographic features and substrate elastic features as well as the lack of mechanistic studies. Herein, wide-scale surface roughness gradient hydrogels, integrating the surface roughness from nanoscale to microscale with controllable stiffness, were developed via soft lithography with precise surface morphology. Based on this promising platform, we systematically studied the mechanosensitive response of human mesenchymal stem cells (MSCs) to a broad range of roughnesses (200 nm to 1.2 μm for R q) and different substrate stiffnesses. We observed that MSCs responded to surface roughness in a stiffness-dependent manner by reorganizing the surface hierarchical structure. Surprisingly, the cellular mechanoresponse and osteogenesis were obviously enhanced on very soft hydrogels (3.8 kPa) with high surface roughness, which was comparable to or even better than that on smooth stiff substrates. These findings extend our understanding of the interactions between cells and biomaterials, highlighting an effective noninvasive approach to regulate stem cell fate via synergetic physical cues.

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Cellular uptake, evolution, and excretion of silica nanoparticles in human cells

et al. 2011

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A systematic study on the interaction of silica nanoparticles (NPs) with human cells has been carried out in the present work. Endocytosis and exocytosis are identified as major pathways for NPs entering, and exiting the cells, respectively. Most of the NPs are found to be enclosed in membrane bounded organelles, which are fairly stable (against rupture) as very few NPs are released into the cytoplasm. The nanoparticle-cell interaction is a dynamic process, and the amount of NPs inside the cells is affected by both the amount and morphology (degree of aggregation) of NPs in the medium. These interaction characteristics determine the low cytotoxicity of SiO(2) NPs at low feeding concentration.

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Zhiqin Chu

Unambiguous observation of shape effects on cellular fate of nanoparticles

Controllable Drug Release and Simultaneously Carrier Decomposition of SiO₂-Drug Composite Nanoparticles

Optical imaging of localized chemical events using programmable diamond quantum nanosensors

Surface Roughness and Substrate Stiffness Synergize To Drive Cellular Mechanoresponse

Cellular uptake, evolution, and excretion of silica nanoparticles in human cells

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Zhiqin Chu

Unambiguous observation of shape effects on cellular fate of nanoparticles

Controllable Drug Release and Simultaneously Carrier Decomposition of SiO2-Drug Composite Nanoparticles

Optical imaging of localized chemical events using programmable diamond quantum nanosensors

Surface Roughness and Substrate Stiffness Synergize To Drive Cellular Mechanoresponse

Cellular uptake, evolution, and excretion of silica nanoparticles in human cells

Contact Info

Product

Resources

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Controllable Drug Release and Simultaneously Carrier Decomposition of SiO₂-Drug Composite Nanoparticles