Bioconjugates for targeted delivery of therapeutic oligonucleotides

Xin, Ming; Laing, Brian

doi:10.1016/j.addr.2015.02.002

Cited by 64 publications

(53 citation statements)

References 101 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In contrast, maleimide and triazol linkages (the result of click chemistry based attachment) are much more stable. The main attachment sites are the 3´-and 5´-terminal hydroxyls [47]. For siRNA, the sense strand shows higher tolerance for ligand attachment, but 3´-antisense modification is also an attractive approach.…”

Section: Pegylated Oligonucleotidesmentioning

confidence: 99%

Therapeutic Oligonucleotides with Polyethylene Glycol Modifications

Winkler

2015

Future Med. Chem.

View full text Add to dashboard Cite

In the field of oligonucleotide drugs, the attachment of PEG is a well-established strategy to prevent enzymatic degradation and avoid renal elimination. Pegaptanib and other oligonucleotides in clinical development utilize the attachment of linear or branched high molecular weight PEG chains for increase of accumulation and duration of the effect after local or systemic application. The length of PEG chains is decisive for the pharmacokinetic and pharmacodynamic effects. Longer chains increase circulation times, but generally decrease gene-silencing efficiencies for antisense and siRNA agents and binding affinities for aptamers. Shorter chains are less efficient in preventing renal filtration, but have also less impact on the gene-silencing machinery and binding kinetics.

show abstract

Section: Pegylated Oligonucleotidesmentioning

confidence: 99%

Therapeutic Oligonucleotides with Polyethylene Glycol Modifications

Winkler

2015

Future Med. Chem.

View full text Add to dashboard Cite

show abstract

“…Preliminary results involving interference tests are provided in the Results section, and a brief background on interference issues is given there. For further details on aptamers in the context of nanopore transduction detection see [17][18][19], and in general see [20][21][22][23][24]. Further details on antibodies pertinent to nanopore detection are placed in the Suppl., including diagrammatic figures and structural details from various references [25][26][27][28][29][30][31][32].…”

Section: Managing Common Interference Agents and Aptamers And Antibomentioning

confidence: 99%

“…Reprinted with permission of [18]. A schematic for typical antibody N-glycosylation is shown (drawn from results on the equine IGHD gene [22]), where one possible N-glycosylation site is indicated in region CH2, and three possible N-glycosylation sites are indicated in region CH3. N-glycosylation consists of a covalent bond (glycosidic) between a biantennary N-glycan (in humans) and asparagine (amino acid 'N', thus N-glycan).…”

Section: S3 Managing Common Interference Agents and Antibodies As Eamentioning

confidence: 99%

Biological system analysis using a nanopore transduction detector: from miRNA validation, to viral monitoring, to gene circuit feedback studies

Winters‐Hilt¹

2017

asms

View full text Add to dashboard Cite

The system biologist is currently lacking a general-use method for a gene circuit 'voltmeter' or gene system algorithm 'print statement'. What is needed is a non-destructive, carrier non-modifying, means of testing 'live' biological systems at the single-molecule level. A method using the nanopore transduction detector (NTD) is demonstrated for single-molecule characterization in some situations, so may provide what is lacking. An important aspect of this approach is that use can be made of inexpensive antibody, protein, aptamer, duplex nucleic acid, or nucleic acid annealing molecules (for miRNA and viral monitoring) that have specific binding to the system component of interest. The NTD transducer's specific binding can also be designed to have low affinity binding as needed, such that there can be a 'catch and release' on low copy-number molecular components, such that there is not a disruption to the molecular system under study. NTD transducers are typically constructed by linking a binding moiety of interest to a 14 Stephen Winters-Hilt nanopore current modulator, where the modulator is designed to be electrophoretically drawn to the channel and partly captured, with its captured end distinctively modulating the flow of ions through the channel. Using inexpensive (commoditized) biomolecular components, such as DNA hairpins, this allows for an easily constructed, versatile, platform for biosensing. High specificity high affinity binding also allows a very versatile platform for assaying at the single molecule level, even down to the single isoform level, including molecular substructure profiling, such as glycosylation profiling in antibodies. An inexpensive commoditized pathway for constructing nanopore transducers is demonstrated. Nanopore transduction detector based reporter/event-transducer molecules may serve as a means to perform multicomponent mRNA-miRNA-protein and protein-protein systems analysis in general settings.

show abstract

“…Design and development of advanced delivery systems have notably increased the siRNA therapeutics in clinical trials and most of these are targeted via systemic delivery (Ozcan et al, 2015;Chakraborty et al, 2017). Many groups have reported systemic delivery of siRNA with different carrier systems such as bioconjugates (Ming and Laing, 2015;Sivakumar et al, 2018;Srimanee et al, 2018), complexes (Biswas and Torchilin, 2013;Nussbaumer et al, 2016;Takemoto and Nishiyama, 2017) and nanoparticles (Patil and Panyam, 2009;Kozielski et al, 2013;Lin et al, 2014;Tezgel et al, 2018). Recent developments have been the combinatorial formulation of carriers to form complexes on the nanoscale for the systemic delivery of siRNA therapeutics (Garg et al, 2016;Lee and Ahn, 2018;Zheng et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Systemic Delivery of Small Interfering RNA Therapeutics: Obstacles and Advances

Chandela

Ueno

2019

RAS

View full text Add to dashboard Cite

RNA interference (RNAi) has emerged as a critical tool for genetic therapeutics. Within the last two decades, there have been extensive investigations in the systemic delivery of these drugs but the obstacles in in vivo delivery have possessed a great difficulty in their administration. These developments led to the advances in systemic administration with designing and incorporation of various drug carriers, including bioconjugate systems, polymeric complexes, organic and inorganic nanoparticles. However, successful translation of these drug delivery systems for the clinical application has still been a great setback for these class of pharmaceutics. In order to improve their competency and applicability, systemic evaluation of currently available carrier systems is required. In this review, we focus on the obstacles in the systemic administration of small interfering RNAs (siRNAs) and the advances with various carrier systems to overcome the limitations of these obstacles. General obstacles in siRNA delivery have been discussed with major emphasis on the barriers at different stages of systemic administration. Then, advances in their application for targeted delivery with rationally designed carrier systems such as bioconjugates, polymeric complexes, and nanoparticles have been introduced. Lastly, we discuss the progress and state of clinical studies of siRNA therapeutics with perspectives of clinical potential.

show abstract

Bioconjugates for targeted delivery of therapeutic oligonucleotides

Cited by 64 publications

References 101 publications

Therapeutic Oligonucleotides with Polyethylene Glycol Modifications

Therapeutic Oligonucleotides with Polyethylene Glycol Modifications

Biological system analysis using a nanopore transduction detector: from miRNA validation, to viral monitoring, to gene circuit feedback studies

Systemic Delivery of Small Interfering RNA Therapeutics: Obstacles and Advances

Contact Info

Product

Resources

About