Encapsulating Active Pharmaceutical Ingredients in Self‐Assembling Adamantanes with Short DNA Zippers

Grießer, Helmut; Schwenger, Alexander; Richert, Clemens

doi:10.1002/cmdc.201700466

Cited by 5 publications

(8 citation statements)

References 34 publications

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“…Either synthesis started from adamantane tetraol ( 1 , dubbed “TOA”), which was reacted with a phosphoramidite building block of uridine for solid‐phase RNA synthesis, using the TBDMS protocol. The aliphatic alcohol was considered unproblematic in terms of possible toxicity, [11] and the arms are entirely made up of unmodified RNA.…”

Section: Resultsmentioning

confidence: 99%

“…Material formation through multivalent hybridization of the arms of branched DNA hybrids alone, or in combination with connector duplexes featuring sticky ends, has been reported before. [5][6][7][8][9][10][11][12] The underlying multivalent hybridization events usually require shorter duplex lengths than those of linear strands, so that dinucleotides can suffice to induce assembly into a material. [5] Even in light of these earlier findings, the current results are surprising.…”

Section: Resultsmentioning

confidence: 99%

“…The hybridization networks formed by such species can capture a range of different active pharmaceutical ingredients and release them into serum from the resulting solid. [11] Further, it was recently shown that hybridization networks made up of hybrids and linear duplexes as spacers or binding sites can encapsulate proteins, either by non-specific capture upon precipitation or based on sequence-specific binding events. [12] The resulting hybrid materials can stabilize proteins against denaturation.…”

Section: Introductionmentioning

confidence: 99%

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Hybridization Networks of mRNA and Branched RNA Hybrids

et al. 2020

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Messenger RNA (mRNA) is emerging as an attractive biopolymer for therapy and vaccination. To become suitable for vaccination, mRNA is usually converted to a biomaterial, using cationic peptides, polymers or lipids. An alternative form of converting mRNA into a material is demonstrated that uses branched oligoribonucleotide hybrids with the ability to hybridize with one or more regions of the mRNA sequence. Two such hybrids with hexamer arms and adamantane tetraol as branching element were prepared by solution‐phase synthesis. When a rabies mRNA was treated with the branched hybrids at 1 M NaCl concentration, biomaterials formed that contained both of the nucleic acids. These results show that branched oligoribonucleotides are an alternative to the often toxic reagents commonly used to formulate mRNA for medical applications.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Hybridization Networks of mRNA and Branched RNA Hybrids

et al. 2020

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“…Our solution‐phases syntheses give functional, monodisperse compounds of up to 10 kDa molecular weight with an unusually high number of “sticky ends” and are easy to scale up. Since branched oligonucleotides have the potential to encapsulate active pharmaceutical ingredients, we are planning to study formulations that are stable at acidic pH, as experienced upon uptake into endosomes, and can release active ingredients at the near‐neutral pH of the cytosol.…”

Section: Resultsmentioning

confidence: 99%

“…Unlike other DNA‐based materials that are produced from synthetic DNA, the hybrids are inexpensive to prepare, using solution‐phase reactions only . The materials described thus far are formed as precipitates that can take up small molecules as guests, including active pharmaceutical ingredients, but not as hydrogels. Hydrogels based on DNA, including plasmid DNA, have been used as delivery vehicles for insulin, as metamaterials with shape memory, or as a medium for encapsulating quantum dots .…”

Section: Introductionmentioning

confidence: 99%

A Three‐State System Based on Branched DNA Hybrids

Richert

2018

Chemistry A European J

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There is a need for materials that respond to chemical or physical stimuli through a change in their structure. While a transition between water-soluble form and solid is not uncommon for DNA-based structures, systems that transition between three different states at room temperature and ambient pressure are rare. Here we report the preparation of branched DNA hybrids with eight oligodeoxycytidylate arms via solution-phase, H-phosphonate-based synthesis. Some hybrids assemble into hydrogels upon lowering the pH, acting as efficient gelators at pH 4-6, but can also transition into a more condensed solid state form upon exposure to divalent cations. Together with the homogeneous solutions that the i-motif-forming compounds give at neutral pH, three-state systems result. Each state has its own color, if chromophores are included in the system. The assembly and gelation properties can be tuned by choosing the chain length of the arms. Their responsive properties make the dC-rich DNA hybrids candidates for smart material applications.

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Turning DNA Binding Motifs into a Material for Flow Cells

Feldner

Wolfrum

Richert

2019

Chemistry A European J

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Nanoscale assemblies of DNA strands are readily designed and can be generated in a wide range of shapes and sizes. Turning them into solids that bind biomolecules reversibly, so that they can act as active material in flow cells, is a challenge. Among the biomolecular ligands, cofactors are of particular interest because they are often the most expensive reagents of biochemical transformations, for which controlled release and recycling are desirable. We have recently described DNA triplex motifs that bind adenine‐containing cofactors, such as NAD, FAD and ATP, reversibly with low micromolar affinity. We sought ways to convert the soluble DNA motifs into a macroporous solid for cofactor binding. While assemblies of linear and branched DNA motifs produced hydrogels with undesirable properties, long DNA triplexes treated with protamine gave materials suitable for flow cells. Using exchangeable cells in a flow system, thermally controlled loading and discharge were demonstrated. Employing a flow cell loaded with ATP, bioluminescence was induced through thermal release of the cofactor. The results show that materials generated from functional DNA structures can be successfully employed in macroscopic devices.

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Encapsulating Active Pharmaceutical Ingredients in Self‐Assembling Adamantanes with Short DNA Zippers

Cited by 5 publications

References 34 publications

Hybridization Networks of mRNA and Branched RNA Hybrids

Hybridization Networks of mRNA and Branched RNA Hybrids

A Three‐State System Based on Branched DNA Hybrids

Turning DNA Binding Motifs into a Material for Flow Cells

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