Project description:The fast dynamics occurring in natural processes increases the difficulty of creating biomaterials capable of mimicking Nature. Within synthetic biomaterials, water-soluble supramolecular polymers show great potential in mimicking the dynamic behavior of these natural processes. In particular, benzene-1,3,5-tricaboxamide (BTA)-based supramolecular polymers have shown to be highly dynamic through the exchange of monomers within and between fibers, but their suitability as biomaterials has not been yet explored. Herein we systematically study the interactions of BTA supramolecular polymers bearing either tetraethylene glycol or mannose units at the periphery with different biological entities. When BTA fibers were incubated with bovine serum albumin (BSA), the protein conformation was only affected by the fibers containing tetraethylene glycol at the periphery (BTA-OEG4). Coarse-grained molecular simulations showed that BSA interacted with BTA-OEG4 fibers rather than with BTA-OEG4 monomers that are present in solution or that may exchange out of the fibers. Microscopy studies revealed that, in the presence of BSA, BTA-OEG4 retained their fiber conformation although their length was slightly shortened. When further incubated with fetal bovine serum (FBS), both long and short fibers were visualized in solution. Nevertheless, in the hydrogel state, the rheological properties were remarkably preserved. Further studies on the cellular compatibility of all the BTA assemblies and mixtures thereof were performed in four different cell lines. A low cytotoxic effect at most concentrations was observed, confirming the suitability of utilizing functional BTA supramolecular polymers as dynamic biomaterials.

Project description:Mimicking the complexity of biological systems with synthetic supramolecular materials requires a deep understanding of the relationship between the structure of the molecule and its self-assembly pattern. Herein, we report a series of water-soluble benzene-1,3,5-tricarboxamide-based di- and tripeptide derivatives modified with small non-bulky terminal amine salt to induce self-assembly into twisted one-dimensional higher-order nanofibers. The morphology of nanofibers strongly depends on the nature, order, and quantity of amino acids in the short peptide fragments and vary from simple cylindrical to complex helical. From observations of several fiber-splitting events, we detected interfiber interactions that always occur in a pairwise manner, which implies that the C3 symmetry of benzene-1,3,5-tricarboxamide-based molecules in higher-order fibers becomes gradually distorted, thus facilitating hydrophobic contact interactions between fibrils. The proposed mechanism of self-assembly through hydrophobic contact allowed the successful design of a compound with pH-responsive morphology, and may find use in the future development of complex hierarchical architectures with controlled functionality.

Project description:In the title molecule, C(9)H(3)Cl(3)O(3), there are three short interactions involving the benzene H atoms and the chloro-formyl Cl atoms. In the crystal, mol-ecules stack along the a axis with no significant non-bonded inter-actions.

Project description:The title compound, C27H18O6, commonly known as phloroglucinol tribenzoate, is a standard unit for the family of benzyl ether dendrimers. The central phloroglucinol residue is close to planar, with out-of-plane distances for the three oxygen atoms of up to 0.095?(3)?Å, while the three attached benzoate groups are approximately planar. One benzoate group is twisted [C-C-O-C torsion angle = 98.2?(3)°] from the central plane, with its carbonyl O atom 2.226?(4)?Å above that plane, while the other two benzoate groups are twisted in the opposite direction [C-C-O-C torsion angles = 24.7?(2) and 54.8?(2)°], so that their carbonyl O atoms are on the other side of, and closer to the central plane, with distances from the plane of 1.743?(4) and 1.206?(4)?Å. One benzoate group is disordered between two conformers, with occupancies of 86.9?(3) and 13.1?(3)%, related by a 143?(1)° rotation about the bond to the central benzene ring. The phenyl groups of the two conformers occupy the same space. The mol-ecule packs in the crystal with two of the three benzoate phenyl rings stacked parallel to symmetry-related counterparts, with perpendicular distances of 3.715?(5) and 3.791?(5)?Å. The parallel rings are slipped away from each other, however, with centroid-centroid distances of 4.122?(2) and 4.363?(2)?Å, respectively.

Project description:Dissipative self-assembly, which requires a continuous supply of fuel to maintain the assembled states far from equilibrium, is the foundation of biological systems. Among a variety of fuels, light, the original fuel of natural dissipative self-assembly, is fundamentally important but remains a challenge to introduce into artificial dissipative self-assemblies. Here, we report an artificial dissipative self-assembly system that is constructed from light-induced amphiphiles. Such dissipative supramolecular assembly is easily performed using protonated sulfonato-merocyanine and chitosan based molecular and macromolecular components in water. Light irradiation induces the assembly of supramolecular nanoparticles, which spontaneously disassemble in the dark due to thermal back relaxation of the molecular switch. Owing to the presence of light-induced amphiphiles and the thermal dissociation mechanism, the lifetimes of these transient supramolecular nanoparticles are highly sensitive to temperature and light power and range from several minutes to hours. By incorporating various fluorophores into transient supramolecular nanoparticles, the processes of aggregation-induced emission and aggregation-caused quenching, along with periodic variations in fluorescent color over time, have been demonstrated. Transient supramolecular assemblies, which act as fluorescence modulators, can also function in human hepatocellular cancer cells.

Project description:The meth-oxy group of the title compound, C(7)H(5)Cl(3)O, is rotated out of the plane of the aromatic ring system, with a dihedral angle of 84.11 (13)°, due to the two bulky ortho-chloro substituents.

Project description:The asymmetric unit of the title compound, C(10)H(14)N(4)·C(6)H(6)O(3)·H(2)O, contains one mol-ecule of benzene-1,3,5-triol, two half-molecules of 1,1'-butane-1,4-diyldi-1H-imidazole (each molecule is centrosymmetric) and one solvent water mol-ecule. In the crystal structure, inter-molecular O-H⋯O and O-H⋯N hydrogen bonds link all mol-ecules into a three-dimensional supra-molecular network.

Project description:Analogues of benzene-1,3,5-tricarboxamide bearing combinations of different alkyl chains (dodecyl to octadecyl) and ester-linked PEG (polyethylene glycol) chains are shown to self-assemble into either micelles or nanotapes in aqueous solution, depending on the architecture (number of alkyl vs PEG chains). The cytotoxicity to cells is selectively greater for breast cancer cells than fibroblast controls in a dose-dependent manner. The compounds show strong stability, retaining their self-assembled structures at low pH (relevant to acidic tumor conditions) and in buffer and cell culture media.

Project description:The asymmetric unit of the title compound, C(12)H(12)O(6), contains two essentially identical mol-ecules related by a pseudo-inversion centre. The three acet-oxy groups in each mol-ecule are essentially planar and are tilted, in a regular propeller-style arrangement, with their normals oriented between 56.72?(12) and 76.35?(9)° from the normal to the mean plane of the central C(6) ring; in each mol-ecule the three carbonyl O atoms are on the same side of the C(6) ring, with the C(ring)-O-C-Me bonds in a trans conformation. The principal inter-molecular contacts appear to be C-H??-ring inter-actions; each C(6) ring has such a contact to both faces of the ring; in addition, each mol-ecule has two inter-molecular C-H?O contacts with H?O distances less than 2.55?Å.

Project description:The structure of the title compound, C(6)H(6)O(3), has been redetermined at low temperature [room-temperature structure: Maartmann-Moe (1965 ?). Acta Cryst. 19, 155-157]. The mol-ecule is planar with approximate D(3h) point symmetry, yet it crystallizes in the chiral ortho-rhom-bic space group P2(1)2(1)2(1) with a three-dimensional hydrogen-bonding network containing infinite O-H?O-H?O-H chains.