Transcytosis and brain uptake of transferrin-containing nanoparticles by tuning avidity to transferrin receptor

Wiley, Devin T.; Webster, Paul; Gale, Aaron; Davis, Mark E.

doi:10.1073/pnas.1307152110

Cited by 398 publications

(352 citation statements)

References 23 publications

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“…Transferrin-containing gold NPs can enter and accumulate in the brain parenchyma after systemic administration in mice through a receptor-mediated transcytosis pathway. 5 Furthermore, the accumulation of 100 nm PS-COOH NPs within the lysosomes of the in vitro BBB was observed by Raghnaill et al 6 Iron oxide (IO) NPs, ZnO NPs, and titanium dioxide (TiO 2 ) NPs have also been found to be translocated to the brain in various animal models. observed the accumulation of TiO 2 NPs in the mouse hippocampus after intragastric administration, and this accumulation led to hippocampal apoptosis and impairment in spatial recognition memory.…”

Section: Introductionmentioning

confidence: 93%

Central nervous system toxicity of metallic nanoparticles

Feng¹,

Chen²,

Zhang³

et al. 2015

IJN

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Nanomaterials (NMs) are increasingly used for the therapy, diagnosis, and monitoring of disease- or drug-induced mechanisms in the human biological system. In view of their small size, after certain modifications, NMs have the capacity to bypass or cross the blood–brain barrier. Nanotechnology is particularly advantageous in the field of neurology. Examples may include the utilization of nanoparticle (NP)-based drug carriers to readily cross the blood–brain barrier to treat central nervous system (CNS) diseases, nanoscaffolds for axonal regeneration, nanoelectromechanical systems in neurological operations, and NPs in molecular imaging and CNS imaging. However, NPs can also be potentially hazardous to the CNS in terms of nano-neurotoxicity via several possible mechanisms, such as oxidative stress, autophagy, and lysosome dysfunction, and the activation of certain signaling pathways. In this review, we discuss the dual effect of NMs on the CNS and the mechanisms involved. The limitations of the current research are also discussed.

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Section: Introductionmentioning

confidence: 93%

Central nervous system toxicity of metallic nanoparticles

Feng¹,

Chen²,

Zhang³

et al. 2015

IJN

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“…Firstly, increasing the administered MNP dose is a common strategy, but this is a non-specific approach and doses required for efficacious uptake within the CNS can be predicted to carry a toxicity risk. The second strategy involves adding targeting ligands to the outer tip of PEG molecules at the particle surface (for example targeted to transferrin and insulin receptors, which are abundant at the BBB, and can facilitate transfer of appropriately-tagged molecules/particles into the CNS parenchyma [65]). However, transferrin receptors are also abundant in the liver -a major MPS component -so targets should be sought with greater BBB specificity.…”

Section: Figure 4 Extent Of Particle Uptake Varies Greatly Between Nmentioning

confidence: 99%

‘Stealth’ nanoparticles evade neural immune cells but also evade major brain cell populations: Implications for PEG-based neurotherapeutics

Jenkins

Weinberg

al-Shakli

et al. 2016

Journal of Controlled Release

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“…Wiley and colleagues investigated the tradeoff between size (surface area) of the nanoparticles and the number of transferrin molecules on the nanoparticles for sufficient interactions with the transferrin receptors. 280 This research introduced a rational design strategy to optimize nanoparticle composition for transport through BBB.…”

Section: Magnetic Nanoparticles For Crossing the Blood Brain Barriermentioning

confidence: 99%

Acute and Chronic Neural Stimulation via Mechano-Sensitive Ion Channels

Tay

2018

Springer Theses

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Neural stimulation techniques for eliciting calcium influx can elucidate the physiological roles of specific neural populations. To overcome some of the limitations of existing techniques such as poor specificity and noxious effects of heat, I developed a technology for non-invasive control of neural activities using magnetic forces and magnetic nanoparticles (MNPs) which offer deep tissue penetration and controllable dosage. Extensive investigations with different neurotoxins and experimental conditions support that the mechanism of magnetic stimulation that involves membrane-bound MNPs transducing magnetic forces into mechanical stretching of the cell membrane to enhance the opening probability of mechano-sensitive N-type calcium ion channels to induce calcium influx.Making use of the ability of neural networks to actively regulate their ratio of excitatory to inhibitory ion channel/receptor, I also performed chronic magnetic stimulation on fragile X iii syndrome (FXS) model neural networks. We found that chronic magnetic stimulation reduced the density of N-type calcium ion channels whose expression is increased in FXS. This technique demonstrates the potential of using bio-magnetic/mechanical forces to modulate expressions of mechano-sensitive ion channels where they are over-expressed in diseases such as abnormal nociception.Nonetheless, there are still a few areas where the technique can be improved. Firstly, it is the use of MNPs with more uniform properties to have greater control on magnetic stimulations.Secondly, the technique needs to be useful for in vivo studies. Therefore, I started researching on magnetotactic bacteria (MTB) which produce biological MNPs with superior properties such as uniform sizes and highly homogenous magnetic properties with the goal of harvesting MNPs from them.MTB, however, grow extremely slowly and the number of MNPs produced/bacterium is low. One way to overcome this problem is to evolve MTB over-producers of MNPs but this strategy is constrained by the absence of a selection platform that is quantitative and offer high throughput. To overcome this problem, I combined random chemical mutagenesis and selection using a magnetic ratcheting platform to generate and isolate MTB over-producers that produce twice as many MNPs/bacterium after 5 rounds of mutation/selection. I next designed a magnetic microfluidic device and demonstrate as a proof of concept, that it can be coupled to a bioreactor for high throughput microfluidic selection of MTB over-producers.iv

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Transcytosis and brain uptake of transferrin-containing nanoparticles by tuning avidity to transferrin receptor

Cited by 398 publications

References 23 publications

Central nervous system toxicity of metallic nanoparticles

Central nervous system toxicity of metallic nanoparticles

‘Stealth’ nanoparticles evade neural immune cells but also evade major brain cell populations: Implications for PEG-based neurotherapeutics

Acute and Chronic Neural Stimulation via Mechano-Sensitive Ion Channels

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