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2. Supramolecular Copolymers of Peptides and Lipidated Peptides and Their Therapeutic Potential

Author

Ruomeng Qiu, Ivan R. Sasselli, Zaida Álvarez, Hiroaki Sai, Wei Ji, Liam C. Palmer, and Samuel I. Stupp

Subjects
Colloid and Surface Chemistry, Polymers, Thermodynamics, Protein Conformation, beta-Strand, General Chemistry, Peptides, Biochemistry, Protein Structure, Secondary, Catalysis
Abstract

Supramolecular peptide chemistry offers a versatile strategy to create chemical systems useful as new biomaterials with potential to deliver nearly 1000 known candidate peptide therapeutics or integrate other types of bioactivity. We report here on the co-assembly of lipidated β-sheet-forming peptides with soluble short peptides, yielding

Published
2022

3. Growth of Extra-Large Chromophore Supramolecular Polymers for Enhanced Hydrogen Production

Author

Samuel I. Stupp, Michael R. Wasielewski, Alexandra N. Edelbrock, Natalia E. Powers-Riggs, Liam C. Palmer, Steven Weigand, Boris Harutyunyan, Ashwin Narayanan, James V. Passarelli, Adam J. Dannenhoffer, Hiroaki Sai, and Michael J. Bedzyk

Subjects
Materials science, Polymers, Static Electricity, Supramolecular chemistry, Bioengineering, 02 engineering and technology, Polymerization, chemistry.chemical_compound, General Materials Science, Perylene, chemistry.chemical_classification, Mechanical Engineering, General Chemistry, Polymer, Chromophore, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Supramolecular polymers, chemistry, Chemical engineering, Ionic strength, Photocatalysis, 0210 nano-technology, Hydrogen
Abstract

The control of morphology in bioinspired chromophore assemblies is key to the rational design of functional materials for light harvesting. We investigate here morphological changes in perylene monoimide chromophore assemblies during thermal annealing in aqueous environments of high ionic strength to screen electrostatic repulsion. We found that annealing under these conditions leads to the growth of extra-large ribbon-shaped crystalline supramolecular polymers of widths from about 100 nm to several micrometers and lengths from 1 to 10 μm while still maintaining a unimolecular thickness. This growth process was monitored by variable-temperature absorbance spectroscopy, synchrotron X-ray scattering, and confocal microscopy. The extra-large single-crystal-like supramolecular polymers are highly porogenic, thus creating loosely packed hydrogel scaffolds that showed greatly enhanced photocatalytic hydrogen production with turnover numbers as high as 13 500 over ∼110 h compared to 7500 when smaller polymers are used. Our results indicate great functional opportunities in thermally and pathway-controlled supramolecular polymerization.

Published
2021

4. Development of Optimized Tissue-Factor-Targeted Peptide Amphiphile Nanofibers to Slow Noncompressible Torso Hemorrhage

Author

Mia K. Klein, Wolfgang Bergmeier, Erica B. Peters, Timothy A. Pritts, Robert H. Lee, Brooke R. Dandurand, Mark R. Karver, Melina R. Kibbe, Brian Gavitt, Mark D. Struble, Tristan D. Clemons, Nick D. Tsihlis, Liam C. Palmer, Hussein A. Kassam, Jessica R. Rouan, Samuel I. Stupp, and David C. Gillis

Subjects
Nanofibers, General Physics and Astronomy, Hemorrhage, 02 engineering and technology, 010402 general chemistry, Immunofluorescence, 01 natural sciences, Article, Fibrin, Thromboplastin, Mice, Tissue factor, In vivo, medicine, Peptide amphiphile, Animals, General Materials Science, Vein, Whole blood, medicine.diagnostic_test, biology, Chemistry, General Engineering, Torso, 021001 nanoscience & nanotechnology, Molecular biology, Rats, 0104 chemical sciences, medicine.anatomical_structure, Nanofiber, biology.protein, Peptides, 0210 nano-technology
Abstract

Non-compressible torso hemorrhage accounts for a significant portion of preventable trauma deaths. We report here on the development of injectable, targeted supramolecular nanotherapeutics based on peptide amphiphile (PA) molecules that are designed to target tissue factor (TF) and, therefore, selectively localize to sites of injury to slow hemorrhage. Eight TF-targeting sequences were identified, synthesized into PA molecules, co-assembled with non-targeted backbone PA at various weight percentages, and characterized via circular dichroism spectroscopy, transmission electron microscopy, and X-ray scattering. Following intravenous injection in a rat liver hemorrhage model, two of these PA nanofiber co-assemblies exhibited the most specific localization to the site of injury compared to controls (p

Published
2020

5. Light-Driven Expansion of Spiropyran Hydrogels

Author

Chuang Li, Samuel I. Stupp, Aysenur Iscen, Liam C. Palmer, and George C. Schatz

Subjects
Negative phototaxis, Spiropyran, Molecular switch, Indoles, Light, Molecular Structure, Photoswitch, Hydrogels, General Chemistry, Nitro Compounds, 010402 general chemistry, 01 natural sciences, Biochemistry, Lower critical solution temperature, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Chemical engineering, Network covalent bonding, Self-healing hydrogels, Benzopyrans, Merocyanine
Abstract

The incorporation of molecular switches in organic structures is of great interest in the chemical design of stimuli-responsive materials that mimic the complex functions of living systems. Merocyanine dyes that convert to spiropyran moieties upon exposure to visible light have been extensively studied as they can be incorporated in hydrated covalent networks that will expel water when this conversion occurs and induce a volumetric shrinkage. We report here on a sulfonate-based water-soluble photoswitch that, in contrast to the well-known systems, triggers a volumetric expansion in hydrogels upon exposure to photons. Contraction is in turn observed under dark conditions in a highly reversible manner. The novel behavior of the photoswitch incorporated in the covalent network was predicted by coarse-grained simulations of the system's chemical structure. Using pH control and polymeric structures that differ in lower critical solution temperature, we were able to develop hydrogels with highly tunable volumetric expansion. The novel molecular function of the systems developed here led to materials with the negative phototaxis observed in plants and could expand the potential use of hydrogels as sensors, soft robots, and actuators.

Published
2020

6. Correction to 'Supramolecular Interactions and Morphology of Self-Assembling Peptide Amphiphile Nanostructures'

Author

Liam C. Palmer, Ivan R. Sasselli, Sieun Ruth Lee, M. Hussain Sangji, Stacey M. Chin, Hiroaki Sai, and Samuel I. Stupp

Subjects
Nanostructure, Morphology (linguistics), Materials science, Mechanical Engineering, Amphiphile, Supramolecular chemistry, General Materials Science, Bioengineering, Nanotechnology, General Chemistry, Condensed Matter Physics, Self-assembling peptide
Published
2021

7. Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure

Author

Charlotte H. Chen, Liam C. Palmer, and Samuel I. Stupp

Subjects
Hot Temperature, Nanostructure, Supramolecular chemistry, Bioengineering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Article, Freezing, Peptide amphiphile, Non-covalent interactions, General Materials Science, Cell adhesion, chemistry.chemical_classification, Chemistry, Mechanical Engineering, Self repair, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Nanostructures, 0104 chemical sciences, Nanofiber, Biophysics, Self-assembly, Peptides, 0210 nano-technology
Abstract

Supramolecular nanostructures formed through self-assembly can have energy landscapes, which determine their structures and functions depending on the pathways selected for their synthesis and processing, and on the conditions they are exposed to after their initial formation. We report here on the structural damage that occurs in supramolecular peptide amphiphile nanostructures, during freezing in aqueous media, and the self-repair pathways that restore their functions. We found that freezing converts long supramolecular nanofibers into shorter ones, compromising their ability to support cell adhesion, but a single heating and cooling cycle reverses the damage and rescues their bioactivity. Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. In addition, we found that nanofibers disrupted during freeze drying also exhibit the ability to undergo thermal self-repair and recovery of their bioactivity, despite the extra disruption caused by the dehydration step. Following both freezing and freeze drying, which shorten the 1D nanostructures, their self-repair capacity through thermally driven elongation is inhibited by kinetically trapped states, which contain highly stable noncovalent interactions that are difficult to rearrange. These states decrease the extent of thermal nanostructure repair, an observation we hypothesize applies to supramolecular systems in general and is mechanistically linked to suppressed molecular exchange dynamics.

Published
2018

8. Water Dynamics from the Surface to the Interior of a Supramolecular Nanostructure

Author

Liam C. Palmer, Samuel I. Stupp, Elad Deiss-Yehiely, Christina J. Newcomb, Timothy J. Keller, Songi Han, Julia H. Ortony, Monica Olvera de la Cruz, and Baofu Qiao

Subjects
chemistry.chemical_classification, Nanostructure, Biomolecule, Supramolecular chemistry, Nanotechnology, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, Catalysis, 0104 chemical sciences, Colloid and Surface Chemistry, Molecular recognition, chemistry, Chemical physics, Molecule, Protein folding, 0210 nano-technology, Nanoscopic scale, Vicinal
Abstract

Water within and surrounding the structure of a biological system adopts context-specific dynamics that mediate virtually all of the events involved in the inner workings of a cell. These events range from protein folding and molecular recognition to the formation of hierarchical structures. Water dynamics are mediated by the chemistry and geometry of interfaces where water and biomolecules meet. Here we investigate experimentally and computationally the translational dynamics of vicinal water molecules within the volume of a supramolecular peptide nanofiber measuring 6.7 nm in diameter. Using Overhauser dynamic nuclear polarization relaxometry, we show that drastic differences exist in water motion within a distance of about one nanometer from the surface, with rapid diffusion in the hydrophobic interior and immobilized water on the nanofiber surface. These results demonstrate that water associated with materials designed at the nanoscale is not simply a solvent, but rather an integral part of their structure and potential functions.

Published
2017

9. Crystal-Phase Transitions and Photocatalysis in Supramolecular Scaffolds

Author

Liam C. Palmer, Job Boekhoven, Adam S. Weingarten, Hiroaki Sai, Adam J. Dannenhoffer, Michael J. Bedzyk, Pascual I. O’Dogherty, Boris Harutyunyan, Michael R. Wasielewski, Andrew Senesi, Taner Aytun, Brian T. Phelan, Ashwin Narayanan, Samuel I. Stupp, Daniel J. Fairfield, and Roman V. Kazantsev

Subjects
Phase transition, Macromolecular Substances, Surface Properties, Static Electricity, Supramolecular chemistry, Ionic bonding, 02 engineering and technology, Imides, 010402 general chemistry, 01 natural sciences, Biochemistry, Phase Transition, Article, Catalysis, Absorbance, Crystal, Condensed Matter::Materials Science, Colloid and Surface Chemistry, Phase (matter), Particle Size, Perylene, Quantitative Biology::Biomolecules, Molecular Structure, Chemistry, Energy landscape, General Chemistry, Chromophore, Photochemical Processes, 021001 nanoscience & nanotechnology, Nanostructures, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, Crystallography, Chemical physics, Thermodynamics, Crystallization, 0210 nano-technology
Abstract

The energy landscape of a supramolecular material can include different molecular packing configurations that differ in stability and function. We report here on a thermally driven crystalline order transition in the landscape of supramolecular nanostructures formed by charged chromophore amphiphiles in salt-containing aqueous solutions. An irreversible transition was observed from a metastable to a stable crystal phase within the nanostructures. In the stable crystalline phase, the molecules end up organized in a short scroll morphology at high ionic strengths and as long helical ribbons at lower salt content. This is interpreted as the result of the competition between electrostatic repulsive forces and attractive molecular interactions. Only the stable phase forms charge-transfer excitons upon exposure to visible light as indicated by absorbance and fluorescence features, second-order harmonic generation microscopy, and femtosecond transient absorbance spectroscopy. Interestingly, the supramolecular reconfiguration to the stable crystalline phase nanostructures enhances photosensitization of a proton reduction catalyst for hydrogen production.

Published
2017

10. Electrostatic Control of Polymorphism in Charged Amphiphile Assemblies

Author

Vinayak P. Dravid, Samuel I. Stupp, Yue Li, Honghao Li, Liam C. Palmer, Michael J. Bedzyk, Changrui Gao, Sumit Kewalramani, and Monica Olvera de la Cruz

Subjects
Materials science, Small-angle X-ray scattering, Bilayer, Ionic bonding, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Micelle, 0104 chemical sciences, Surfaces, Coatings and Films, Crystallography, Transmission electron microscopy, Amphiphile, Materials Chemistry, Peptide amphiphile, Titration, Physical and Theoretical Chemistry, 0210 nano-technology
Abstract

Stimuli-induced structural transformations of molecular assemblies in aqueous solutions are integral to nanotechnological applications and biological processes. In particular, pH responsive amphiphiles as well as proteins with various degrees of ionization can reconfigure in response to pH variations. Here, we use in situ small and wide-angle X-ray scattering (SAXS/WAXS), transmission electron microscopy (TEM), and Monte Carlo simulations to show how charge regulation via pH induces morphological changes in the assembly of a positively charged peptide amphiphile (PA). Monte Carlo simulations and pH titration measurements reveal that ionic correlations in the PA assemblies shift the ionizable amine pK ∼ 8 from pK ∼ 10 in the lysine headgroup. SAXS and TEM show that with increasing pH, the assembly undergoes spherical micelle to cylindrical nanofiber to planar bilayer transitions. SAXS/WAXS reveal that the bilayer leaflets are interdigitated with the tilted PA lipid tails crystallized on a rectangular lattice. The details of the molecular packing in the membrane result from interplay between steric and van der Waals interactions. We speculate that this packing motif is a general feature of bilayers comprised of amphiphilic lipids with large ionic headgroups. Overall, our studies correlate the molecular charge and the morphology for a pH-responsive PA system and provide insights into the Å-scale molecular packing in such assemblies.

Published
2017

11. Long-Range Ordering of Highly Charged Self-Assembled Nanofilaments

Author

Rohan Kumthekar, Monica Olvera de la Cruz, Cheuk Yui Leung, Samuel I. Stupp, Liam C. Palmer, Michael J. Bedzyk, Christina J. Newcomb, and Sumit Kewalramani

Subjects
Ammonium bromide, Molecular Structure, Small-angle X-ray scattering, Nanofibers, Nanotechnology, General Chemistry, Biochemistry, Catalysis, Crystal, chemistry.chemical_compound, Colloid and Surface Chemistry, Azobenzene, chemistry, Chemical physics, Nanofiber, Scattering, Small Angle, Amphiphile, Molecule, Nanoscopic scale
Abstract

Charged nanoscale filaments are well-known in natural systems such as filamentous viruses and the cellular cytoskeleton. The unique properties of these structures have inspired the design of self-assembled nanofibers for applications in regenerative medicine, drug delivery, and catalysis, among others. We report here on an amphiphile of completely different chemistry based on azobenzene and a quaternary ammonium bromide headgroup that self-assembles into highly charged nanofibers in water and orders into two-dimensional crystals. Interestingly small-angle X-ray scattering (SAXS) shows that these fibers of 5.6 nm cross-sectional diameter order into crystalline arrays with remarkably large interfiber spacings of up to 130 nm. Solution concentration and temperature can be adjusted to control the interfiber spacings, and addition of salt destroyed the crystal packing indicating the electrostatic repulsions are necessary for the observed ordering. Our findings here demonstrate the universal nature of this phenomenon in systems of highly charged nanoscale filaments.

Published
2014

12. Supramolecular Chemistry and Self-Assembly in Organic Materials Design

Author

Samuel I. Stupp and Liam C. Palmer

Subjects
chemistry.chemical_classification, Solid-state chemistry, Materials science, General Chemical Engineering, Supramolecular chemistry, Stacking, Nanotechnology, General Chemistry, Hydrophobic effect, Supramolecular polymers, chemistry, Materials Chemistry, Non-covalent interactions, Self-assembly, Supramolecular catalysis
Abstract

Organic materials naturally lend themselves to the crafting of structure and function using the strategies of self-assembly and supramolecular chemistry employed so effectively by biological systems. This perspective illustrates progress over the past two decades on self-assembly in materials chemistry through research on systems where function is directly linked to noncovalent interactions among molecules. The genesis of this approach in chemistry of materials involves the design of relatively simple structures using hydrogen bonding, π–π stacking, metal–ligand interactions, electrostatic forces, strong dipole–dipole association, hydrophobic forces, and steric repulsion. Gradually many new and exciting opportunities have emerged, such as supramolecular nanostructures that assemble into functional bulk materials and supramolecular polymers in which the motif of covalent connections among monomers is imitated by creating one-dimensional assemblies of an arbitrarily large set of molecules in both compositio...

Published
2013

13. Molecular Crystallization Controlled by pH Regulates Mesoscopic Membrane Morphology

Author

Christina J. Newcomb, Graziano Vernizzi, Cheuk Yui Leung, Rastko Sknepnek, Megan A. Greenfield, Sumit Kewalramani, Samuel I. Stupp, Monica Olvera de la Cruz, Michael J. Bedzyk, Liam C. Palmer, and Baofu Qiao

Subjects
Mesoscopic physics, Materials science, Small-angle X-ray scattering, Bilayer, Cell Membrane, Lipid Bilayers, Static Electricity, Molecular Conformation, General Engineering, General Physics and Astronomy, Ionic bonding, Hydrogen-Ion Concentration, Molecular Dynamics Simulation, law.invention, Degree of ionization, Molecular dynamics, Crystallography, Chemical physics, law, General Materials Science, Self-assembly, Crystallization
Abstract

Coassembled molecular structures are known to exhibit a large variety of geometries and morphologies. A grand challenge of self-assembly design is to find techniques to control the crystal symmetries and overall morphologies of multicomponent systems. By mixing +3 and -1 ionic amphiphiles, we assemble crystalline ionic bilayers in a large variety of geometries that resemble polyhedral cellular crystalline shells and archaea wall envelopes. We combine TEM with SAXS and WAXS to characterize the coassembled structures from the mesoscopic to nanometer scale. The degree of ionization of the amphiphiles and their intermolecular electrostatic interactions are controlled by varying pH. At low and high pH values, we observe closed, faceted vesicles with two-dimensional hexagonal molecular arrangements, and at intermediate pH, we observe ribbons with rectangular-C packing. Furthermore, as pH increases, we observe interdigitation of the bilayer leaflets. Accurate atomistic molecular dynamics simulations explain the pH-dependent bilayer thickness changes and also reveal bilayers of hexagonally packed tails at low pH, where only a small fraction of anionic headgroups is charged. Coarse-grained simulations show that the mesoscale geometries at low pH are faceted vesicles where liquid-like edges separate flat crystalline domains. Our simulations indicate that the curved-to-polyhedral shape transition can be controlled by tuning the tail density in regions where sharp bends can form the polyhedral edges. In particular, the pH acts to control the overall morphology of the ionic bilayers by changing the local crystalline order of the amphiphile tails.

Published
2012

14. Self-Assembly of Highly Ordered Peptide Amphiphile Metalloporphyrin Arrays

Author

H. Christopher Fry, Samuel I. Stupp, Matthew J. Medina, Liam C. Palmer, Jamie M. Garcia, David J. Gosztola, Ulises M. Ricoy, and Maxim P. Nikiforov

Subjects
Models, Molecular, chemistry.chemical_classification, Circular dichroism, Stereochemistry, Protoporphyrins, Peptide, General Chemistry, Biochemistry, Porphyrin, Protein Structure, Secondary, Catalysis, Crystallography, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Amphiphile, Organometallic Compounds, Peptide amphiphile, Self-assembly, Peptides, Peptide sequence, Hemin
Abstract

Long fibers assembled from peptide amphiphiles capable of binding the metalloporphyrin zinc protoporphyrin IX ((PPIX)Zn) have been synthesized. Rational peptide design was employed to generate a peptide, c16-AHL(3)K(3)-CO(2)H, capable of forming a β-sheet structure that propagates into larger fibrous structures. A porphyrin-binding site, a single histidine, was engineered into the peptide sequence in order to bind (PPIX)Zn to provide photophysical functionality. The resulting system indicates control from the molecular level to the macromolecular level with a high order of porphyrin organization. UV/visible and circular dichroism spectroscopies were employed to detail molecular organization, whereas electron microscopy and atomic force microscopy aided in macromolecular characterization. Preliminary picosecond transient absorption data are also reported. Reduced hemin, (PPIX)Fe(II), was also employed to highlight the material's versatility and tunability.

Published
2012

15. Grooved Nanowires from Self-Assembling Hairpin Molecules for Solar Cells

Author

Liam C. Palmer, Wei-Wen Tsai, Taner Aytun, Samuel I. Stupp, and Ian D. Tevis

Subjects
Materials science, Fullerene, Nanostructure, Organic solar cell, Nanowires, Electric Conductivity, General Engineering, Nanowire, General Physics and Astronomy, Heterojunction, Nanotechnology, Thiophenes, Microscopy, Atomic Force, Acceptor, Polymer solar cell, Electric Power Supplies, Solar Energy, General Materials Science, Self-assembly
Abstract

One of the challenges facing bulk heterojunction organic solar cells is obtaining organized films during the phase separation of intimately mixed donor and acceptor components. We report here on the use of hairpin-shaped sexithiophene molecules to generate by self-assembly grooved nanowires as the donor component in bulk heterojunction solar cells. Photovoltaic devices were fabricated via spin-casting to produce by solvent evaporation a percolating network of self-assembled nanowires and fullerene acceptors. Thermal annealing was found to increase power conversion efficiencies by promoting domain growth while still maintaining this percolating network of nanostructures. The benefits of self-assembly and grooved nanowires were examined by building devices from a soluble sexithiophene derivative that does not form one-dimensional structures. In these systems, excessive phase separation caused by thermal annealing leads to the formation of defects and lower device efficiencies. We propose that the unique hairpin shape of the self-assembling molecules allows the nanowires as they form to interact well with the fullerenes in receptor-ligand type configurations at the heterojunction of the two domains, thus enhancing device efficiencies by 23%.

Published
2012

16. Self-Assembly and Orientation of Hydrogen-Bonded Oligothiophene Polymorphs at Liquid–Membrane–Liquid Interfaces

Author

Ian D. Tevis, David J. Herman, Ian P. Murray, Samuel I. Stupp, Liam C. Palmer, and David Stone

Subjects
Polymers, Surface Properties, Inorganic chemistry, Nucleation, Supramolecular chemistry, Stacking, Thiophenes, Biochemistry, Catalysis, Dioxanes, chemistry.chemical_compound, Colloid and Surface Chemistry, Aluminum Oxide, Particle Size, Furans, Tetrahydrofuran, chemistry.chemical_classification, Molecular Structure, Hydrogen bond, Hydrogen Bonding, Membranes, Artificial, General Chemistry, Polymer, Solvent, Kinetics, chemistry, Chemical engineering, Self-assembly, Porosity, Toluene
Abstract

One of the challenges in organic systems with semiconducting function is the achievement of molecular orientation over large scales. We report here on the use of self-assembly kinetics to control long-range orientation of a quarterthiophene derivative designed to combine intermolecular π-π stacking and hydrogen bonding among amide groups. Assembly of these molecules in the solution phase is prevented by the hydrogen-bond-accepting solvent tetrahydrofuran, whereas formation of H-aggregates is facilitated in toluene. Rapid evaporation of solvent in a solution of the quarterthiophene in a 2:1:1 mixture of 1,4-dioxane/tetrahydrofuran/toluene leads to self-assembly of kinetically trapped mats of bundled fibers. In great contrast, slow drying in a toluene atmosphere leads to the homogeneous nucleation and growth of ordered structures shaped as rhombohedra or hexagonal prisms depending on concentration. Furthermore, exceedingly slow delivery of toluene from a high molecular weight polymer solution into the system through a porous aluminum oxide membrane results in the growth of highly oriented hexagonal prisms perpendicular to the interface. The amide groups of the compound likely adsorb onto the polar aluminum oxide surface and direct the self-assembly pathway toward heterogeneous nucleation and growth to form hexagonal prisms. We propose that the oriented prismatic polymorph results from the synergy of surface interactions rooted in hydrogen bonding on the solid membrane and the slow kinetics of self-assembly. These observations demonstrate how self-assembly conditions can be used to guide the supramolecular energy landscape to generate vastly different structures. These fundamental principles allowed us to grow oriented prismatic assemblies on transparent indium-doped tin oxide electrodes, which are of interest in organic electronics.

Published
2011

17. Biomimetic Systems for Hydroxyapatite Mineralization Inspired By Bone and Enamel

Author

Samuel I. Stupp, Liam C. Palmer, Christina J. Newcomb, Erik David Spoerke, and Stuart R. Kaltz

Subjects
Mineralized tissues, Enamel paint, Chemistry, Human bone, Nanotechnology, General Chemistry, Mineralization (biology), Bone and Bones, Article, Apatite, Enamel mineralization, Calcification, Physiologic, Durapatite, Biomimetic Materials, visual_art, visual_art.visual_art_medium, Animals, Humans, Dental Enamel, Hybrid material, Biomineralization
Abstract

1.1. Biomineralization The study of biomineralization is not only important to gain an understanding of how mineral-rich tissues are created in vivo but also because it is a great source of inspiration for the design of advanced materials.1-7 Mineralized tissues have remarkable hierarchical structures that have evolved over time to achieve great functions in a large variety of organisms. Organic phases play a key role in templating the structure of mineralized tissues; therefore, their matrices are often hybrid in composition, varying widely in the relative content of organic and inorganic substances. Understanding the complex integration of hard and soft phases that biology achieves in mineralized matrices across scales and its link to properties is knowledge of great value to materials chemistry. At the same time, the synthetic mechanisms used by biology to create mineralized matrices could also offer some useful strategies to create synthetic hybrid materials. Often, the amount of organic material utilized by Nature to modify mechanical properties of mineralized structures is vanishingly small. One example is the role of occluded proteins in the toughness of biogenic calcite.8 The study of mammalian bone and teeth in the biomineralization and biomimetic context is particularly interesting since the information derived could contribute a significant biomedical impact on therapies and strategies to repair or regenerate human mineralized tissues. This is an important area given the continually rising average life span of humans. The materials of interest could be highly sophisticated bioactive scaffolds to regenerate bone and possibly dental tissues as well. This review focuses on the formation of hydroxyapatite (HA) in synthetic systems designed primarily in the biomimetic context of bone or enamel mineralization for therapeutic approaches in repair of human tissues. Bone and enamel share the same mineral composition, HA, but have different morphologies and organic content. Enamel is almost entirely inorganic in composition, and bone has a relatively high organic composition. Knowledge acquired in this field may inspire the chemical synthesis of novel hybrid materials, including apatite-based structures for the regeneration of human bone and dental tissues.

Published
2008

18. Molecular Self-Assembly into One-Dimensional Nanostructures

Author

Liam C. Palmer and Samuel I. Stupp

Subjects
Anthracenes, Circular dichroism, Nanostructure, Chemistry, Supramolecular chemistry, Stereoisomerism, Nanotechnology, General Medicine, General Chemistry, Microscopy, Atomic Force, Article, Nanostructures, Microscopy, Electron, Transmission, Dendrimer, Molecule, Molecular self-assembly, Peptides, Spectroscopy, Nanoscopic scale
Abstract

Self-assembly of small molecules into one-dimensional nanostructures offers many potential applications in electronically and biologically active materials. The recent advances discussed in this Account demonstrate how researchers can use the fundamental principles of supramolecular chemistry to craft the size, shape, and internal structure of nanoscale objects. In each system described here, we used atomic force microscopy (AFM) and transmission electron microscopy (TEM) to study the assembly morphology. Circular dichroism, nuclear magnetic resonance, infrared, and optical spectroscopy provided additional information about the self-assembly behavior in solution at the molecular level. Dendron rod-coil molecules self-assemble into flat or helical ribbons. They can incorporate electronically conductive groups and can be mineralized with inorganic semiconductors. To understand the relative importance of each segment in forming the supramolecular structure, we synthetically modified the dendron, rod, and coil portions. The self-assembly depended on the generation number of the dendron, the number of hydrogen-bonding functions, and the length of the rod and coil segments. We formed chiral helices using a dendron-rod-coil molecule prepared from an enantiomerically enriched coil. Because helical nanostructures are important targets for use in biomaterials, nonlinear optics, and stereoselective catalysis, researchers would like to precisely control their shape and size. Tripeptide-containing peptide lipid molecules assemble into straight or twisted nanofibers in organic solvents. As seen by AFM, the sterics of bulky end groups can tune the helical pitch of these peptide lipid nanofibers in organic solvents. Furthermore, we demonstrated the potential for pitch control using trans-to-cis photoisomerization of a terminal azobenzene group. Other molecules called peptide amphiphiles (PAs) are known to assemble in water into cylindrical nanostructures that appear as nanofiber bundles. Surprisingly, TEM of a PA substituted by a nitrobenzyl group revealed assembly into quadruple helical fibers with a braided morphology. Upon photocleavage of this the nitrobenzyl group, the helices transform into single cylindrical nanofibers. Finally, inspired by the tobacco mosaic virus, we used a dumbbell-shaped, oligo(phenylene ethynylene) template to control the length of a PA nanofiber self-assembly (10 nm). AFM showed complete disappearance of long nanofibers in the presence of this rigid-rod template. Results from quick-freeze/deep-etch TEM and dynamic light scattering demonstrated the templating behavior in aqueous solution. This strategy could provide a general method to control size the length of nonspherical supramolecular nanostructures.

Published
2008

19. Interplay of Thermochromicity and Liquid Crystalline Behavior in Poly(p-phenyleneethynylene)s: π−π Interactions or Planarization of the Conjugated Backbone?

Author

Lioba Kloppenburg, Uwe H. F. Bunz, Dieter Neher, Tzenka Miteva, and Liam C. Palmer

Subjects
Inorganic Chemistry, Thermochromism, Phase transition, Materials science, Polymers and Plastics, Liquid crystalline, Chemical-mechanical planarization, Organic Chemistry, Polymer chemistry, Materials Chemistry, Side chain, Electronic structure, Conjugated system
Published
2000

20. Synthesis and Self-Assembly of the 'Tennis Ball' Dimer and Subsequent Encapsulation of Methane. An Advanced Organic Chemistry Laboratory Experiment

Author

Liam C. Palmer, Fraser Hof, and Julius Rebek

Subjects
chemistry.chemical_classification, Chemistry, Hydrogen bond, Dimer, Nanotechnology, General Chemistry, Education, Encapsulation (networking), chemistry.chemical_compound, Monomer, Molecule, Non-covalent interactions, Organic chemistry, Tennis ball, Self-assembly
Abstract

While important to the biological and materials sciences, noncovalent interactions, self-folding, and self-assembly often receive little discussion in the undergraduate chemistry curriculum. The synthesis and NMR characterization of a molecular "tennis ball" in an advanced undergraduate organic chemistry laboratory is a simple and effective way to introduce the relevance of these concepts. In appropriate solvents, the monomer dimerizes through a seam of eight hydrogen bonds with encapsulation of a guest molecule and symmetry reminiscent of a tennis ball. The entire experiment can be completed in three lab periods, however large-scale synthetic preparation of the starting monomer by a teaching assistant would reduce the laboratory to a single lab period for NMR studies.

Published
2001

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