Development of a targeted siRNA delivery system using FOL-PEG-PEI conjugate

Biswal, Bijesh K.; Debata, Niladri Bihari; Verma, Rama Shanker

doi:10.1007/s11033-009-9853-3

Cited by 31 publications

(18 citation statements)

References 22 publications

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“…In an attempt to fabricate multifunctional delivery system which could facilitate target specific treatment of tumor, Verma group studied the folate receptor (FR)-mediated delivery of dihydrofolate reductase (DHFR) siRNA to silence the DHFR gene in FR positive KB cells (Biswal et al, 2010). A DHFR siRNA sequence was cloned into a pSUPER-RNAi vector and complexed with the folate-polyethylene glycol-PEI (FOL-PEG-PEI) conjugate.…”

Section: Polyethyleniminementioning

confidence: 99%

Polymers in Small-Interfering RNA Delivery

Singha

Namgung

Kim

2011

Nucleic Acid Therapeutics

181

112

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This review will cover the current strategies that are being adopted to efficiently deliver small interfering RNA using nonviral vectors, including the use of polymers such as polyethylenimine, poly(lactic-co-glycolic acid), polypeptides, chitosan, cyclodextrin, dendrimers, and polymers-containing different nanoparticles. The article will provide a brief and concise account of underlying principle of these polymeric vectors and their structural and functional modifications which were intended to serve different purposes to affect efficient therapeutic outcome of small-interfering RNA delivery. The modifications of these polymeric vectors will be discussed with reference to stimuli-responsiveness, target specific delivery, and incorporation of nanoconstructs such as carbon nanotubes, gold nanoparticles, and silica nanoparticles. The emergence of small-interfering RNA as the potential therapeutic agent and its mode of action will also be mentioned in a nutshell.

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Section: Polyethyleniminementioning

confidence: 99%

Polymers in Small-Interfering RNA Delivery

Singha

Namgung

Kim

2011

Nucleic Acid Therapeutics

181

112

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“…34 Researchers have designed various types of novel copolymers, such as pH-sensitive, temperature-sensitive, light-sensitive, magnetic-sensitive, ultrasound-sensitive, redox-sensitive, and enzyme-degraded copolymers, in order to solve the issue of low transfection efficiency of the PEGylated nanoparticles. [35][36][37][38] In this study, redox-sensitive PEG-SS-PLL was synthesized and used to deliver the novel nanoparticle complex PEG-SS-PLL/siVEGF. We investigated the transfection efficiency, cytotoxicity in vitro, tumor-inhibitory effect in vivo, and the mechanism of antitumor effect of the complex.…”

Section: Discussionmentioning

confidence: 99%

Polyethylene glycol–poly(ε-benzyloxycarbonyl-L-lysine)-conjugated VEGF siRNA for antiangiogenic gene therapy in hepatocellular carcinoma

Wang¹,

Gao²,

Gu³

et al. 2017

IJN

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A polyethylene glycol–poly(ε-benzyloxycarbonyl- l -lysine) (PEG-SS-PLL) block copolymer based on a disulfide-linked, novel biodegradable catiomer bearing a PEG-sheddable shell was developed to avoid “PEG dilemma” in nanoparticle intracellular tracking of PEG-PLL where PEG was nondegradable. However, PEG-SS-PLL catiomers have not been used to deliver small interfering VEGF RNA (siVEGF) in antiangiogenesis gene therapy. In this study, we aimed to investigate whether this novel biodegradable catiomer can deliver siVEGF into cancer cells and at the same time have an antitumor effect in a xenograft mouse model. It was found that PEG-SS-PLL efficiently delivered siVEGF with negligible cytotoxicity, and significantly decreased the expression of VEGF at both the messenger-RNA and protein levels both in vitro and in vivo, and thus tumor growth was inhibited. Our findings demonstrated that PEG-SS-PLL/siVEGF could potentially be applied to antiangiogenesis gene therapy for hepatocellular carcinoma.

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“…Liposomes versatile and flexible system protection of the siRNA targeting possible membrane fusion and triggered drug release form aggregates with serum proteins immunogenic limited delivery efficiency in vivo [63] PEGylation decreased blood clearence [64] incorporation of fusogenic lipids enhanced bioavailability of siRNA [65] apolipoprotein A 95% knockdown without immunotoxicity targeted to the liver [66] pH-sensitive histidinelysine peptide inhibition of tumor growth in a pancreatic cancer model [67] peptide from Rabies Virus glycoprotein brain targeting [68] SNALPs -Stabilized Nucleic Acid Lipid Particles PEG-derivatized cationic lipid with stabilized lipid bilayer fusogenic prolonged blood circulation 80-90% efficiency after siRNA transfection into liver [34] SPANosomes sorbitan monooleate high siRNA incorporation efficiency efficient endosomal escape and cytosolic delivery 60-80% gene knockdown [69,70] Polyethylenimine -PEI toxicity of high molecular weight PEI proton sponge effect for efficient release from endosomes [21] hydrophobic lipid anchor improved cellular uptake [71] folate folate receptor mediated uptake [42] galactose and pullulan liver targeted [43,72] PEI-PEG-copolymer efficient siRNA release 75%gene knockdown efficiency suppression of tumor growth [73] bioreducible poly(amido ethylenimine) (SS-PAEI) complete release of siRNA in a reductive environment [62] Poly(dl-lactide-co-glycolide) -PLGA degraded under physiological conditions degradation rate can be controlled by composition of the polymer nucleic acid encapsulation no endosomal escape mechanism [74] cationic segments (polyamines) good binding and protections of siRNA disruption of endosomal membranes [75] poly(ethylene glycol)-poly (d,l-lactide) cationic lipic suppressed tumor growth in a breast cancer murine xenograft model [76] Chitosan biodegradable, no/low immunogenicity low siRNA transfection efficiency [77,78] salt complexes excellent cell survival high gene silencing [79] α-tocopherol succinate enhanced cellular uptake [47] thiamine pyrophosphate >70% gene silencing [80] RGD peptide targeting to cancer cells [44] guanidinylation decreased cytotoxicity and enhanced cellular internalization of siRNA enhanced gene-silencing efficiency …”

Section: Sirna Delivery System Examples For Modifications Characterismentioning

confidence: 99%

“…However, incorporation of ligands increased targeting to specific cells and tissues. PEI was modified with folate to be taken up by folate receptor expressing tumors [42], or by pullulan, a water-soluble polysaccharide, to direct it to Brought to you by | University of St Andrews Scotland Authenticated | 138.251.14.35 Download Date | 1/12/14 2:28 PM [60]. Both linear and branched PEI induced proinflammatory cytokine production and hepatic damage, although linear PEI was less toxic [61].…”

Section: Targeting and Cellular Uptakementioning

confidence: 99%

Vehicles for Small Interfering RNA transfection: Exosomes versus Synthetic Nanocarriers

Duechler¹

2013

DNA and RNA Nanotechnology

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Therapies based on RNA interference (RNAi) hold a great potential for targeted interference of the expression of specific genes. Small-interfering RNAs (siRNA) and micro-RNAs interrupt protein synthesis by inducing the degradation of messenger RNAs or by blocking their translation. RNAibased therapies can modulate the expression of otherwise undruggable target proteins. Full exploitation of RNAi for medical purposes depends on efficient and safe methods for delivery of small RNAs to the target cells. Tremendous effort has gone into the development of synthetic carriers to meet all requirements for efficient delivery of nucleic acids into particular tissues. Recently, exosomes unveiled their function as a natural communication system which can be utilized for the transport of small RNAs into target cells. In this review, the capabilities of exosomes as delivery vehicles for small RNAs are compared to synthetic carrier systems. The step by step requirements for efficient transfection are considered: production of the vehicle, RNA loading, protection against degradation, lack of immunogenicity, targeting possibilities, cellular uptake, cytotoxicity, RNA release into the cytoplasm and gene silencing efficiency. An exosomebased siRNA delivery system shows many advantages over conventional transfection agents, however, some crucial issues need further optimization before broad clinical application can be realized.

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Development of a targeted siRNA delivery system using FOL-PEG-PEI conjugate

Cited by 31 publications

References 22 publications

Polymers in Small-Interfering RNA Delivery

Polymers in Small-Interfering RNA Delivery

Polyethylene glycol–poly(ε-benzyloxycarbonyl-L-lysine)-conjugated VEGF siRNA for antiangiogenic gene therapy in hepatocellular carcinoma

Vehicles for Small Interfering RNA transfection: Exosomes versus Synthetic Nanocarriers

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Development of a targeted siRNA delivery system using FOL-PEG-PEI conjugate

Cited by 31 publications

References 22 publications

Polymers in Small-Interfering RNA Delivery

Polymers in Small-Interfering RNA Delivery

Polyethylene glycol&ndash;poly(&epsilon;-benzyloxycarbonyl-L-lysine)-conjugated VEGF siRNA for antiangiogenic gene therapy in hepatocellular carcinoma

Vehicles for Small Interfering RNA transfection: Exosomes versus Synthetic Nanocarriers

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Polyethylene glycol–poly(ε-benzyloxycarbonyl-L-lysine)-conjugated VEGF siRNA for antiangiogenic gene therapy in hepatocellular carcinoma