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1. Breaking Parallel Orientation of Rods via a Dendritic Architecture toward Diverse Supramolecular Structures

   https://doi.org/10.1002/anie.201904749  

   Zhang, Ruimeng ; Feng, Xueyan ; Zhang, Rui ; Shan, Wenpeng ; Su, Zebin ; Mao, Jialin ; Wesdemiotis, Chrys ; Huang, Jiahao ; Yan, Xiao‐Yun ; Liu, Tong ; et al ( July 2019 , Angewandte Chemie International Edition)

   Self‐assembled nanostructures of rod‐like molecules are commonly limited to nematic or layered smectic structures dominated by the parallel arrangement of the rod‐like components. Distinct self‐assembly behavior of four categories of dendritic rods constructed by placing a tri(hydroxy) group at the apex of dendritic oligo‐fluorenes is observed. Designed hydrogen bonding and dendritic architecture break the parallel arrangement of the rods, resulting in molecules with specific (fan‐like or cone‐like) shapes. While the fan‐shaped molecules tend to form hexagonal packing cylindrical phases, the cone‐shaped molecules could form spherical motifs to pack into various ordered structures, including the Frank–Kasper A15 phase and dodecagonal quasicrystal. This study provides a model system to engineer diverse supramolecular structures by rod‐like molecules and sheds new light into the mechanisms of the formation of unconventional spherical packing structures in soft matter.

    

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2. Anisotropic Rod‐Shaped Particles Influence Injectable Granular Hydrogel Properties and Cell Invasion

   https://doi.org/10.1002/adma.202109194  

   Qazi, Taimoor H. ; Wu, Jingyu ; Muir, Victoria G. ; Weintraub, Shoshana ; Gullbrand, Sarah E. ; Lee, Daeyeon ; Issadore, David ; Burdick, Jason A. ( January 2022 , Advanced Materials)

   Granular hydrogels have emerged as a new class of injectable and porous biomaterials that improve integration with host tissue when compared to solid hydrogels. Granular hydrogels are typically prepared using spherical particles and this study considers whether particle shape (i.e., isotropic spheres vs anisotropic rods) influences granular hydrogel properties and cellular invasion. Simulations predict that anisotropic rods influence pore shape and interconnectivity, as well as bead transport through granular assemblies. Photo‐cross‐linkable norbornene‐modified hyaluronic acid is used to produce spherical and rod‐shaped particles using microfluidic droplet generators and formed into shear‐thinning and self‐healing granular hydrogels, with particle shape influencing mechanics and injectability. Rod‐shaped particles form granular hydrogels that have anisotropic and interconnected pores, with pore size and number influenced by particle shape and degree of packing. Robust in vitro sprouting of endothelial cells from embedded cellular spheroids is observed with rod‐shaped particles, including higher sprouting densities and sprout lengths when compared to hydrogels with spherical particles. Cell and vessel invasion into granular hydrogels when injected subcutaneously in vivo are significantly greater with rod‐shaped particles, whereas a gradient of cellularity is observed with spherical particles. Overall, this work demonstrates potentially superior functional properties of granular hydrogels with rod‐shaped particles for tissue repair.

    

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3. Molecular Geometry‐Directed Self‐Recognition in the Self‐Assembly of Giant Amphiphiles

   https://doi.org/10.1002/marc.202200216  

   Zhou, Yifan ; Luo, Jiancheng ; Liu, Tong ; Wen, Tao ; Williams‐Pavlantos, Kayla ; Wesdemiotis, Chrys ; Cheng, Stephen Z. D. ; Liu, Tianbo ( May 2022 , Macromolecular Rapid Communications)

   Three sets of polyoxometalate (POM)‐based amphiphilic hybrid macromolecules with different rigidity in their organic tails are used as models to understand the effect of molecular rigidity on their possible self‐recognition feature during self‐assembly processes. Self‐recognition is achieved in the mixed solution of two structurally similar, sphere‐rigid T‐shape‐linked oligofluorene(TOF₄) rod amphiphiles, with the hydrophilic clusters being Anderson (Anderson‐TOF₄) and Dawson (Dawson‐TOF₄), respectively. Anderson‐TOF₄is observed to self‐assemble into onion‐like multilayer structures and Dawson‐TOF₄forms multilayer vesicles. The self‐assembly is controlled by the interdigitation of hydrophobic rods and the counterion‐mediated attraction among charged hydrophilic inorganic clusters. When the hydrophobic blocks are less rigid, e.g., partially rigid polystyrene and fully flexible alkyl chains, self‐recognition is not observed, attributing to the flexible conformation of hydrophobic molecules in the solvophobic domain. This study reveals that the self‐recognition among amphiphiles can be achieved by the geometrical limitation of the supramolecular structure due to the rigidity of solvophobic domains.

    

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4. A kinetic analysis of mouse rod and cone photoreceptor responses

   https://doi.org/10.1113/JP279524  

   Reingruber, Jürgen ; Ingram, Norianne T. ; Griffis, Khris G. ; Fain, Gordon L. ( July 2020 , The Journal of Physiology)

   Most vertebrate eyes have rods for dim‐light vision and cones for brighter light and higher temporal sensitivity.

   Rods evolved from cone‐like precursors through expression of different transduction genes or the same genes at different expression levels, but we do not know which molecular differences were most important.

   We approached this problem by analysing rod and cone responses with the same model but with different values for model parameters. We showed that, in addition to outer‐segment volume, the most important differences between rods and cones are: (1) decreased transduction gain, reflecting smaller amplification in the G‐protein cascade; (2) a faster rate of turnover of the second messenger cGMP in darkness; and (3) an accelerated rate of decay of the effector enzyme phosphodiesterase and perhaps also of activated visual pigment.

   We believe our analysis has identified the principal alterations during evolution responsible for the duplex retina.

   Most vertebrates have rod and cone photoreceptors, which differ in their sensitivity and response kinetics. We know that rods evolved from cone‐like precursors through the expression of different transduction genes or the same genes at different levels, but we do not know which molecular differences were most important. We have approached this problem in mouse retina by analysing the kinetic differences between rod flash responses and recent voltage‐clamp recordings of cone flash responses, using a model incorporating the principal features of photoreceptor transduction. We apply a novel method of analysis using the log‐transform of the current, and we ask which of the model's dynamic parameters need be changed to transform the flash response of a rod into that of a cone. The most important changes are a decrease in the gain of the response, reflecting a reduction in amplification of the transduction cascade; an increase in the rate of turnover of cGMP in darkness; and an increase in the rate of decay of activated phosphodiesterase, with perhaps also an increase in the rate of decay of light‐activated visual pigment. Although we cannot exclude other differences, and in particular alterations in the Ca²⁺economy of the photoreceptors, we believe that we have identified the kinetic parameters principally responsible for the differences in the flash responses of the two kinds of photoreceptors, which were likely during evolution to have resulted in the duplex retina.

    

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5. Self-Assembly in Mixtures of Charged Lobed Particles

   https://doi.org/10.3389/fphy.2022.936385  

   Srivastava, Arpita ; Rocha, Brunno C. ; Vashisth, Harish ( July 2022 , Frontiers in Physics)

   We report coarse-grained Langevin dynamics simulations of homogeneous mixtures of lobed colloidal particles with opposite charges. We show that dumbbell, trigonal planar, tetrahedral, square planar, trigonal bipyramidal, and octahedral shaped particles form distinct self-assemblies including chains, sheets, crystalline, and spherical structures. The dumbbell and square planar particles predominantly form chains and sheets while other particles form network-like self-assembled morphologies. At higher temperatures and lower charges, non-planar particles form three-dimensional aggregates. We further report on packing arrangements of particles which lead to differences in porosities within self-assembled morphologies. Our results show that the trigonal planar particles form larger porous structures. The self-assembled structures that we report are potentially useful in designing porous biomaterials for biomedical applications. 

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