Nanoparticle dynamics in hydrogel networks with controlled defects.

The effect of nanoscale defects on nanoparticle dynamics in defective tetra-poly(ethylene glycol) (tetra-PEG) hydrogels is investigated using single particle tracking. In a swollen nearly homogeneous hydrogel, PEG-functionalized quantum dot (QD) probes with a similar hydrodynamic diameter (dh = 15.1 nm) to the mesh size (〈ξs〉 = 16.3 nm), are primarily immobile. As defects are introduced to the network by reaction-tuning, both the percentage of mobile QDs and the size of displacements increase as the number and size of the defects increase with hydrolysis time, although a large portion of the QDs remain immobile. To probe the effect of nanoparticle size on dynamics in defective networks, the transport of dh = 47.1 nm fluorescent polystyrene (PS) and dh = 9.6 nm PEG-functionalized QDs is investigated. The PS nanoparticles are immobile in all hydrogels, even in highly defective networks with an open structure. Conversely, the smaller QDs are more sensitive to perturbations in the network structure with an increased percentage of mobile particles and larger diffusion coefficients compared to the larger QDs and PS nanoparticles. The differences in nanoparticle mobility as a function of size suggests that particles of different sizes probe different length scales of the defects, indicating that metrics such as the confinement ratio alone cannot predict bulk dynamics in these systems. This study provides insight into designing hydrogels with controlled transport properties, with particular importance for degradable hydrogels for drug delivery applications.

[1]  Cherie R. Kagan,et al.  Monodisperse Nanocrystal Superparticles through a Source–Sink Emulsion System , 2022, Chemistry of Materials.

[2]  F. Picchioni,et al.  Relationship between Structure and Rheology of Hydrogels for Various Applications , 2021, Gels.

[3]  Jiahui He,et al.  Functional Hydrogels as Wound Dressing to Enhance Wound Healing. , 2021, ACS nano.

[4]  Kelly M. Schultz,et al.  Human mesenchymal stem cell-engineered length scale dependent rheology of the pericellular region measured with bi-disperse multiple particle tracking microrheology. , 2020, Acta biomaterialia.

[5]  M. J. Boyle,et al.  Particle tracking of nanoparticles in soft matter , 2020 .

[6]  Koen J. A. Martens,et al.  Spatiotemporal Heterogeneity of κ-Carrageenan Gels Investigated via Single-Particle-Tracking Fluorescence Microscopy , 2020, Langmuir : the ACS journal of surfaces and colloids.

[7]  M. Rathinam,et al.  Predicting Drug Release From Degradable Hydrogels Using Fluorescence Correlation Spectroscopy and Mathematical Modeling , 2019, Front. Bioeng. Biotechnol..

[8]  Alberto Salleo,et al.  Redefining near-unity luminescence in quantum dots with photothermal threshold quantum yield , 2019, Science.

[9]  Dany J. Munoz-Pinto,et al.  An improved correlation to predict molecular weight between crosslinks based on equilibrium degree of swelling of hydrogel networks. , 2018, Journal of biomedical materials research. Part B, Applied biomaterials.

[10]  April M. Kloxin,et al.  Tuning and Predicting Mesh Size and Protein Release from Step Growth Hydrogels. , 2017, Biomacromolecules.

[11]  Xuhong Guo,et al.  Chitosan cross-linked poly(acrylic acid) hydrogels: Drug release control and mechanism. , 2017, Colloids and surfaces. B, Biointerfaces.

[12]  R. Composto,et al.  Network confinement and heterogeneity slows nanoparticle diffusion in polymer gels. , 2017, The Journal of chemical physics.

[13]  Xin Chen,et al.  A review on polymeric hydrogel membranes for wound dressing applications: PVA-based hydrogel dressings , 2017, Journal of advanced research.

[14]  T. Sakai,et al.  Electrophoretic mobility of semi-flexible double-stranded DNA in defect-controlled polymer networks: Mechanism investigation and role of structural parameters. , 2015, The Journal of chemical physics.

[15]  M. Rubinstein,et al.  Hopping Diffusion of Nanoparticles in Polymer Matrices , 2015, Macromolecules.

[16]  D. Santi,et al.  Biodegradable tetra-PEG hydrogels as carriers for a releasable drug delivery system. , 2015, Bioconjugate chemistry.

[17]  T. Sakai,et al.  Kinetic Aspect on Gelation Mechanism of Tetra-PEG Hydrogel , 2014 .

[18]  J. Tinevez,et al.  TNF and IL-1 exhibit distinct ubiquitin requirements for inducing NEMO–IKK supramolecular structures , 2014, The Journal of cell biology.

[19]  R. Hayward,et al.  Characterization of Heterogeneous Polyacrylamide Hydrogels by Tracking of Single Quantum Dots , 2014 .

[20]  J. Gong,et al.  Fracture energy of polymer gels with controlled network structures. , 2013, The Journal of chemical physics.

[21]  W. Hennink,et al.  Interpenetrating Polymer Networks polysaccharide hydrogels for drug delivery and tissue engineering. , 2013, Advanced drug delivery reviews.

[22]  T. Sakai,et al.  Ultimate elongation of polymer gels with controlled network structure , 2013 .

[23]  T. Sakai Gelation mechanism and mechanical properties of Tetra-PEG gel , 2013 .

[24]  H. Noguchi,et al.  Rubber elasticity for incomplete polymer networks. , 2012, The Journal of chemical physics.

[25]  T. Sakai,et al.  Connectivity and Structural Defects in Model Hydrogels: A Combined Proton NMR and Monte Carlo Simulation Study , 2011 .

[26]  Ung-il Chung,et al.  Examination of the Theories of Rubber Elasticity Using an Ideal Polymer Network , 2011 .

[27]  S. Diez,et al.  Tracking single particles and elongated filaments with nanometer precision. , 2011, Biophysical journal.

[28]  T. Sakai,et al.  Evaluation of Gelation Kinetics of Tetra-PEG Gel , 2010 .

[29]  Jason A. Burdick,et al.  Sequential crosslinking to control cellular spreading in 3-dimensional hydrogels , 2009 .

[30]  T. Sakai,et al.  Structure Characterization of Tetra-PEG Gel by Small-Angle Neutron Scattering , 2009 .

[31]  Yuji Yamamoto,et al.  Design and Fabrication of a High-Strength Hydrogel with Ideally Homogeneous Network Structure from Tetrahedron-like Macromonomers , 2008 .

[32]  K. Saalwächter Proton multiple-quantum NMR for the study of chain dynamics and structural constraints in polymeric soft materials , 2007 .

[33]  K. Saalwächter Detection of heterogeneities in dry and swollen polymer networks by proton low-field NMR spectroscopy. , 2003, Journal of the American Chemical Society.

[34]  Chang-ho Park,et al.  Concentrating Cellulases from Fermented Broth Using a Temperature‐Sensitive Hydrogel , 1992 .

[35]  L. Leibler,et al.  Large-scale heterogeneities in randomly cross-linked networks , 1988 .

[36]  H. Winter Can the gel point of a cross-linking polymer be detected by the G′ – G″ crossover? , 1987 .

[37]  E. Geissler,et al.  Structural inhomogeneities in the range 2.5-2500 .ANG. in polyacrylamide gels , 1985 .

[38]  P. Dynes,et al.  Relationship between viscoelastic properties and gelation in thermosetting systems , 1982 .