Effects of chain flexibility on the properties of DNA hydrogels

Pan, Wei; Wen, Hao; Niu, Lin; Su, Cuicui; Liu, Chenyang; Zhao, Jiang; Mao, Chengde; Liang, Dehai

doi:10.1039/c6sm00283h

Cited by 25 publications

(29 citation statements)

References 35 publications

(48 reference statements)

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“…These rigid and flexible designs were mixed in fractions between 100, 50, 25, and 0% of rigid linkers at approximately 4% w/v DNA content. The respective mixtures were found to have the corresponding storage moduli of 450, 600, 1800 and 1800 Pa at frequencies between 0.1-10 Hz and gelling temperatures of 40.1, 43.6, 49.4, and 48.7 • C [65]. This example as well demonstrated counterintuitive results where a greater fraction of flexible linkers increased the storage moduli, which was due to an increased number of hybridized crosslinks with the flexible linkers.…”

Section: Nanostructuredmentioning

confidence: 78%

“…This approach yielded counterintuitive results where an increase in valency and hybridization interaction yielded lower storage moduli, which demonstrates the need to consider the availability of binding sites in nanostructured designs. Pan et al conducted an alternative study of linear self-assembling DNA hydrogels which further supports this need for flexibility in the internal structure to enhance macroscopic stiffness [65]. Specifically, 2-3 short DNA strands were designed to hybridize sequentially with one strand designed with a short 10 nt sticky overhang that could hybridize to another long tiled dsDNA strand with a self-complementary overhang.…”

Section: Nanostructuredmentioning

confidence: 98%

“…Nanostructured DNA hydrogels are most commonly constructed from multivalent DNA nanostars (DNAns) (Figure 1c) [50,[61][62][63]. Alternatively, short multidomain self-assembling strands have been used to construct complementary linear sections of dsDNA crosslinked by complementary overhangs (Figure 1d) [64,65]. Jiang et al designed a single short DNA strand with 3-6 self-complementary binding domains of 12-20 nt in length to form a DNA hydrogel.…”

Section: Nanostructuredmentioning

confidence: 99%

See 2 more Smart Citations

Mechanical Properties of DNA Hydrogels: Towards Highly Programmable Biomaterials

Bush

Veneziano

2021

Applied Sciences

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DNA hydrogels are self-assembled biomaterials that rely on Watson–Crick base pairing to form large-scale programmable three-dimensional networks of nanostructured DNA components. The unique mechanical and biochemical properties of DNA, along with its biocompatibility, make it a suitable material for the assembly of hydrogels with controllable mechanical properties and composition that could be used in several biomedical applications, including the design of novel multifunctional biomaterials. Numerous studies that have recently emerged, demonstrate the assembly of functional DNA hydrogels that are responsive to stimuli such as pH, light, temperature, biomolecules, and programmable strand-displacement reaction cascades. Recent studies have investigated the role of different factors such as linker flexibility, functionality, and chemical crosslinking on the macroscale mechanical properties of DNA hydrogels. In this review, we present the existing data and methods regarding the mechanical design of pure DNA hydrogels and hybrid DNA hydrogels, and their use as hydrogels for cell culture. The aim of this review is to facilitate further study and development of DNA hydrogels towards utilizing their full potential as multifeatured and highly programmable biomaterials with controlled mechanical properties.

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Section: Nanostructuredmentioning

confidence: 78%

Section: Nanostructuredmentioning

confidence: 98%

Section: Nanostructuredmentioning

confidence: 99%

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Mechanical Properties of DNA Hydrogels: Towards Highly Programmable Biomaterials

Bush

Veneziano

2021

Applied Sciences

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“…In particular, local inhomogeneities with well-defined nanopores and mechanical properties may be built into the network, as different DNA blocks can be made to hybridize at different temperatures ( 34 ). Indeed, recent shear rheological studies on macroscopic samples ( 3 , 35 , 36 ), here referred to as bulk rheological studies, showed that the specific structure and connectivity of DNA nanostars have a strong influence on their macroscopic mechanical response. However, these low-frequency measurements only describe the systems macroscopic, long-time viscoelastic response and cannot describe how more local relaxation times change as the system goes through the melting transition.…”

mentioning

confidence: 99%

“…Here, we present microrheology studies using diffusing wave spectroscopy (DWS) ( 37 , 38 ) to study the equilibrium elastic and viscous moduli of our DNA gels over a much larger frequency range than that available in bulk rheology ( 39 – 42 ). In particular, using sealed sample chambers allowed us to perform these measurements over a large temperature range without fear of changes in the samples due to evaporation, which is problematic in bulk rheology ( 35 , 43 ). We show that DWS enables us to link the system’s characteristic binding–unbinding processes with the local and global viscoelastic properties of the gel over a temperature range that covers the full melting region between the DNA nanostars.…”

mentioning

confidence: 99%

Microrheology of DNA hydrogels

Xing

Caciagli

Cao

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

107

127

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SignificanceWhile widely known as the molecule of life, DNA is also an amazing building block at the nanoscale, since it allows us to design and program the structure and dynamics of functional nanomaterials. We exploit the programmability of DNA to achieve control over the rheology of self-assembled hydrogels, which have elastic or viscous behavior (similar to that of slime) that is finely regulated by temperature. Using microrheology to investigate the mechanical properties of DNA hydrogels at the microlength scale, we map the viscoelastic response over a broad range of frequencies and temperatures. The deep understanding in the fundamental physics provides a way to design DNA-based materials with precise control over the structure stability and rigidity at molecular level.

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DNA Droplets: Intelligent, Dynamic Fluid

et al. 2022

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Figure 1. Overview of DNA droplets as a hybrid from DNA nanotechnology and liquid-liquid phase separation (LLPS) studies. A) DNA droplets, micro-scale condensates of DNA nanostructures (DNA motifs) self-assembled via sticky ends (SEs). A Y-shaped DNA motif (Y-motif) is a branched nanostructure of three single-stranded DNAs (ssDNAs) hybridized to form the branching stems. At the end of each branch, a single-stranded SE protrudes. Two basic features are highlighted: (i) Programmable interactions. DNA droplets favor sequence-specifically selective interactions as encoded in the SE sequences. (ii) Programmability in mechanical properties.The number of the SEs in a single DNA motif, serving as the valency, can be designed to determine the macroscopic rheological properties, including diffusion coefficient and viscoelastic behavior. Adapted with permission. [29]

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Effects of chain flexibility on the properties of DNA hydrogels

Cited by 25 publications

References 35 publications

Mechanical Properties of DNA Hydrogels: Towards Highly Programmable Biomaterials

Mechanical Properties of DNA Hydrogels: Towards Highly Programmable Biomaterials

Microrheology of DNA hydrogels

DNA Droplets: Intelligent, Dynamic Fluid

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