Qin Wang  Xiaoxia Xia  Wenwen Huang  Yinan Lin  Qiaobing Xu  David L. Kaplan 《Advanced functional materials》2014,24(27):4303-4310

The need for dynamic, elastomeric polymeric biomaterials remains high, with few options with tunable control of mechanical properties, and environmental responses. Yet the diversity of these types of protein polymers pursued for biomaterials‐related needs remains limited. Robust high‐throughput synthesis and characterization methods will address the need to expand options for protein‐polymers for a range of applications. Here, a combinatorial library approach with high throughput screening is used to select specific examples of dynamic protein silk‐elastin‐like polypeptides (SELPs) with unique stimuli responsive features, including tensile strength and adhesion. Using this approach, 64 different SELPs with different sequences and molecular weights are selected out of over 2000 recombinant E. coli colonies. New understanding of sequence‐function relationships with this family of proteins is gained through this combinatorial‐screening approach and can provide a guide to future library designs. Further, this approach yields new families of SELPs to match specific material functions.  相似文献   

    

Christopher M. Madl  Lily M. Katz  Sarah C. Heilshorn 《Advanced functional materials》2016,26(21):3612-3620

Covalently‐crosslinked hydrogels are commonly used as 3D matrices for cell culture and transplantation. However, the crosslinking chemistries used to prepare these gels generally cross‐react with functional groups present on the cell surface, potentially leading to cytotoxicity and other undesired effects. Bio‐orthogonal chemistries have been developed that do not react with biologically relevant functional groups, thereby preventing these undesirable side reactions. However, previously developed biomaterials using these chemistries still possess less than ideal properties for cell encapsulation, such as slow gelation kinetics and limited tuning of matrix mechanics and biochemistry. Here, engineered elastin‐like proteins (ELPs) are developed that crosslink via strain‐promoted azide‐alkyne cycloaddition (SPAAC) or Staudinger ligation. The SPAAC‐crosslinked materials form gels within seconds and complete gelation within minutes. These hydrogels support the encapsulation and phenotypic maintenance of human mesenchymal stem cells, human umbilical vein endothelial cells, and murine neural progenitor cells. SPAAC‐ELP gels exhibit independent tuning of stiffness and cell adhesion, with significantly improved cell viability and spreading observed in materials containing a fibronectin‐derived arginine‐glycine‐aspartic acid (RGD) domain. The crosslinking chemistry used permits further material functionalization, even in the presence of cells and serum. These hydrogels are anticipated to be useful in a wide range of applications, including therapeutic cell delivery and bioprinting.  相似文献   

    

Bhavana Mohanraj  Gang Duan  Ana Peredo  Miju Kim  Fuquan Tu  Daeyeon Lee  George R. Dodge  Robert L. Mauck 《Advanced functional materials》2019,29(15)

Delivery of biofactors in a precise and controlled fashion remains a clinical challenge. Stimuli‐responsive delivery systems can facilitate “on‐demand” release of therapeutics in response to a variety of physiologic triggering mechanisms (e.g., pH, temperature). However, few systems to date have taken advantage of mechanical inputs from the microenvironment to initiate drug release. Here, mechanically activated microcapsules (MAMCs) are designed to deliver therapeutics in response to the mechanically loaded environment of regenerating musculoskeletal tissues, with the ultimate goal of furthering tissue repair. To establish a suite of microcapsules with different thresholds for mechanoactivation, MAMC physical dimensions and composition are first manipulated, and their mechano‐response under both direct 2D compression and in 3D matrices mimicking the extracellular matrix properties and dynamic loading environment of regenerating tissue, is evaluated. To demonstrate the feasibility of this delivery system, an engineered cartilage model is used to test the efficacy of mechanically instigated release of transforming growth factor‐β3 on the chondrogenesis of mesenchymal stem cells. These data establish a novel platform by which to tune the release of therapeutics and/or regenerative factors based on the physiologic mechanical loading environment and will find widespread application in the repair and regeneration of musculoskeletal tissues.  相似文献   

    

Michael M. Kämpf  Erik H. Christen  Martin Ehrbar  Marie Daoud‐El Baba  Ghislaine Charpin‐El Hamri  Martin Fussenegger  Wilfried Weber 《Advanced functional materials》2010,20(15):2534-2538

Gene therapy scientists have developed expression systems for therapeutic transgenes within patients, which must be seamlessly integrated into the patient's physiology by developing sophisticated control mechanisms to titrate expression levels of the transgenes into the therapeutic window. However, despite these efforts, gene‐based medicine still faces security concerns related to the administration of the therapeutic transgene vector. Here, molecular tools developed for therapeutic transgene expression can readily be transferred to materials science to design a humanized drug depot that can be implanted into mice and enables the trigger‐inducible release of a therapeutic protein in response to a small‐molecule inducer. The drug depot is constructed by embedding the vascular endothelial growth factor (VEGF₁₂₁) as model therapeutic protein into a hydrogel consisting of linear polyacrylamide crosslinked with a homodimeric variant of the human FK‐binding protein 12 (F_M), originally developed for gene therapeutic applications, as well as with dimethylsuberimidate. Administrating increasing concentrations of the inducer molecule FK506 triggers the dissociation of F_M thereby loosening the hydrogel structure and releasing the VEGF₁₂₁ payload in a dose‐adjustable manner. Subcutaneous implantation of the drug depot into mice and subsequent administration of the inducer by injection or by oral intake triggers the release of VEGF₁₂₁ as monitored in the mouse serum. This study is the first demonstration of a stimuli‐responsive hydrogel that can be used in mammals to release a therapeutic protein on demand by the application of a small‐molecule stimulus. This trigger‐inducible release is a starting point for the further development of externally controlled drug depots for patient‐compliant administration of biopharmaceuticals.  相似文献   

    

Jörg G. Werner  Brendan T. Deveney  Saraf Nawar  David A. Weitz 《Advanced functional materials》2018,28(39)

Dynamic microcapsules are reported that exhibit shell membranes with fast and reversible changes in permeability in response to external stimuli. A hydrophobic anhydride monomer is employed in the thiol–ene polymerization as a disguised precursor for the acid‐containing shells; this enables the direct encapsulation of aqueous cargo in the liquid core using microfluidic fabrication of water‐in‐oil‐in‐water double emulsion drops. The poly(anhydride) shells hydrolyze in their aqueous environment without further chemical treatment, yielding cross‐linked poly(acid) microcapsules that exhibit trigger‐responsive and reversible property changes. The microcapsule shell can actively be switched numerous times between impermeable and permeable due to the exceptional mechanical properties of the thiol–ene network that prevent rupture or failure of the membrane, allowing it to withstand the mechanical stresses imposed on the capsule during the dynamic property changes. The permeability and molecular weight cutoff of the microcapsules can dynamically be controlled with triggers such as pH and ionic environment. The reversibly triggered changes in permeability of the shell exhibit a response time of seconds, enabling actively adjustable release profiles, as well as on‐demand capture, trapping, and release of cargo molecules with molecular selectivity and fast on‐off rates.  相似文献   

    

Madeline Vauthier  Loïc Jierry  Jamerson Carneiro Oliveira  Lilia Hassouna  Vincent Roucoules  Florence Bally‐Le Gall 《Advanced functional materials》2019,29(10)

Stimuli‐responsive materials have properties that depend on the environment in which they are used. In most cases, the material itself is formulated to react to the corresponding stimulus. However, many phenomena occur at the surface of the material. In this context, the design and the investigation of the reactivity of stimuli‐responsive surfaces are particularly interesting. More precisely, this review focuses on functional coatings that react via Diels–Alder (DA) chemistry, a thermoreversible reaction between a diene and a dienophile. According to the nature of the substrate, these coatings are mainly based on self‐assembled monolayers or silane assemblies, on polydopamine derivatives, or on polymer thin films deposited by vapor‐phase processes including plasma polymerization. The different works discussed here show that interfacial thermoreversible reactions occur between a DA‐functionalized surface and a DA reactant in solution but also between two solid substrates are possible. The direct cycloaddition is always described in the cited papers but the reversibility of the reaction is less discussed. The latter however remains very challenging for smart applications in material science.  相似文献   

    

Sebastian Henke  Andreas Schneemann  Roland A. Fischer 《Advanced functional materials》2013,23(48):5966-5966

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Sebastian Henke  Andreas Schneemann  Roland A. Fischer 《Advanced functional materials》2013,23(48):5990-5996

Functionalized metal–organic frameworks (fu‐MOFs) of general formula [Zn₂(fu‐L)₂dabco]_n show unprecedentedly large uniaxial positive and negative thermal expansion (fu‐L = alkoxy functionalized 1,4‐benzenedicarboxylate, dabco = 1,4‐diazabicyclo[2.2.2]octane). The magnitude of the volumetric thermal expansion is more comparable to property of liquid water rather than any crystalline solid‐state material. The alkoxy side chains of fu‐L are connected to the framework skeleton but nevertheless exhibit large conformational flexibility. Thermally induced motion of these side chains induces extremely large anisotropic framework expansion and eventually triggers reversible solid state phase transitions to drastically expanded structures. The thermo‐responsive properties of these hybrid solid–liquid materials are precisely controlled by the choice and combination of fu‐Ls and depend on functional moieties and chain lengths. In principle, this combinatorial approach allows for a targeted design of extreme thermo‐mechanical properties of MOFs addressing the regime between crystalline solid matter and the liquid state.  相似文献   

Phospholes: Molecular Engineering of “Click”‐Phospholes Towards Self‐Assembled Luminescent Soft Materials (Adv. Funct. Mater. 7/2014)          下载免费PDF全文

Xiaoming He  Jian‐Bin Lin  Wang Hay Kan  Pengcheng Dong  Simon Trudel  Thomas Baumgartner 《Advanced functional materials》2014,24(7):877-877

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Xiaoming He  Jian‐Bin Lin  Wang Hay Kan  Pengcheng Dong  Simon Trudel  Thomas Baumgartner 《Advanced functional materials》2014,24(7):897-906

Inspired by the self‐assembled bilayer structures of natural amphiphilic phospholipids, a new class of highly luminescent “click”‐phospholes with exocyclic alkynyl group at the phosphorus center is reported. These molecules can be easily functionalized with a self‐assembly group to generate neutral “phosphole‐lipids”. This novel approach retains the versatile reactivity of the phosphorus center, allowing further engineering of the photophysical and self‐assembly properties of the materials at a molecular level. The results of this study highlight the importance of being able to balance weak intermolecular interactions for controlling the self‐assembly properties of soft materials. Only molecules with the appropriate set of intermolecular arrangement/interactions show both organogel and liquid crystal mesophases with well‐ordered microstructures. Moreover, an efficient energy transfer of the luminescent materials is demonstrated and applied in the detection of organic solvent vapors.  相似文献   

    

Arif M. Abdullah  Xiuling Li  Paul V. Braun  John A. Rogers  K. Jimmy Hsia 《Advanced functional materials》2020,30(14)

Self‐assembly of 3D structures presents an attractive and scalable route to realize reconfigurable and functionally capable mesoscale devices without human intervention. A common approach for achieving this is to utilize stimuli‐responsive folding of hinged structures, which requires the integration of different materials and/or geometric arrangements along the hinges. It is demonstrated that the inclusion of Kirigami cuts in planar, hingeless bilayer thin sheets can be used to produce complex 3D shapes in an on‐demand manner. Nonlinear finite element models are developed to elucidate the mechanics of shape morphing in bilayer thin sheets and verify the predictions through swelling experiments of planar, millimeter‐scaled PDMS (polydimethylsiloxane) bilayers in organic solvents. Building upon the mechanistic understandings, The transformation of Kirigami‐cut simple bilayers into 3D shapes such as letters from the Roman alphabet (to make “ADVANCED FUNCTIONAL MATERIALS”) and open/closed polyhedral architectures is experimentally demonstrated. A possible application of the bilayers as tether‐less optical metamaterials with dynamically tunable light transmission and reflection behaviors is also shown. As the proposed mechanistic design principles could be applied to a variety of materials, this research broadly contributes toward the development of smart, tetherless, and reconfigurable multifunctional systems.  相似文献   

    

Aaliyah B. Shodeinde  Andrew C. Murphy  Heidi F. Oldenkamp  Abhishek S. Potdar  Catherine M. Ludolph  Nicholas A. Peppas 《Advanced functional materials》2020,30(37)

Autoimmune diseases are a group of debilitating illnesses that are often idiopathic in nature. The steady rise in the prevalence of these conditions warrants new approaches for diagnosis and treatment. Stimuli‐responsive biomaterials also known as “smart,” “intelligent,” or “recognitive” biomaterials are widely studied for their applications in drug delivery, biosensing, and tissue engineering due to their ability to produce thermal, optical, chemical, or structural changes upon interacting with the biological environment. Studies within the last decade that harness the recognitive capabilities of these biomaterials toward the development of novel detection and treatment options for autoimmune diseases are critically analyzed.  相似文献   

    

Yi‐Nan Zhang  Reginald K. Avery  Queralt Vallmajo‐Martin  Alexander Assmann  Andrea Vegh  Adnan Memic  Bradley D. Olsen  Nasim Annabi  Ali Khademhosseini 《Advanced functional materials》2015,25(30):4814-4826

Elastin‐like polypeptides (ELPs) are promising for biomedical applications due to their unique thermoresponsive and elastic properties. ELP‐based hydrogels have been produced through chemical and enzymatic crosslinking or photocrosslinking of modified ELPs. Herein, a photocrosslinked ELP gel using only canonical amino acids is presented. The inclusion of thiols from a pair of cysteine residues in the ELP sequence allows disulfide bond formation upon exposure to UV light, leading to the formation of a highly elastic hydrogel. The physical properties of the resulting hydrogel such as mechanical properties and swelling behavior can be easily tuned by controlling ELP concentrations. The biocompatibility of the engineered ELP hydrogels is shown in vitro as well as corroborated in vivo with subcutaneous implantation of hydrogels in rats. ELP constructs demonstrate long‐term structural stability in vivo, and early and progressive host integration with no immune response, suggesting their potential for supporting wound repair. Ultimately, functionalized ELPs demonstrate the ability to function as an in vivo hemostatic material over bleeding wounds.  相似文献   

    

Jie Wei  Xiao‐Jie Ju  Xiao‐Yi Zou  Rui Xie  Wei Wang  Ying‐Mei Liu  Liang‐Yin Chu 《Advanced functional materials》2014,24(22):3312-3323

Novel multi‐stimuli‐responsive microcapsules with adjustable controlled‐release characteristics are prepared by a microfluidic technique. The proposed microcapsules are composed of crosslinked chitosan acting as pH‐responsive capsule membrane, embedded magnetic nanoparticles to realize “site‐specific targeting”, and embedded temperature‐responsive sub‐microspheres serving as “micro‐valves”. By applying an external magnetic field, the prepared smart microcapsules can achieve targeting aggregation at specific sites. Due to acid‐induced swelling of the capsule membranes, the microcapsules exhibit higher release rate at specific acidic sites compared to that at normal sites with physiological pH. More importantly, through controlling the hydrodynamic size of sub‐microsphere “micro‐valves” by regulating the environment temperature, the release rate of drug molecules from the microcapsules can be flexibly adjusted. This kind of multi‐stimuli‐responsive microcapsules with site‐specific targeting and adjustable controlled‐release characteristics provides a new mode for designing “intelligent” controlled‐release systems and is expected to realize more rational drug administration.  相似文献   

Drug Delivery: Multi‐Stimuli‐Responsive Microcapsules for Adjustable Controlled‐Release (Adv. Funct. Mater. 22/2014)          下载免费PDF全文

Jie Wei  Xiao‐Jie Ju  Xiao‐Yi Zou  Rui Xie  Wei Wang  Ying‐Mei Liu  Liang‐Yin Chu 《Advanced functional materials》2014,24(22):3290-3290

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Edgar Guerrero  Alexander Polednik  Melanie Ecker  Alexandra Joshi‐Imre  Wooyeol Choi  Gerardo Gutierrez‐Heredia  Walter E. Voit  Jimin Maeng 《Advanced Electronic Materials》2020,6(4)

Implementing stable electronic components on smart, soft materials can facilitate increasingly complex functionality in body‐worn and implanted devices for biomedical applications. The fabrication and characterization of indium–gallium–zinc oxide (IGZO)‐based Schottky diodes on a thiol–ene/acrylate shape memory polymer (SMP) that softens in response to physiological stimuli, including temperature and moisture, are presented. A platinum–IGZO Schottky junction is formed on the softening polymer assisted by ultraviolet‐ozone (UV‐O₃) surface treatment. The effects of the UV‐O₃ treatment conditions on the Schottky barrier properties are examined. The diode operation is evaluated in dry and wet conditions with varying temperatures up to 75 °C, revealing that the fabricated diodes preserve their performance even after the softening effect (i.e., an orders‐of‐magnitude modulus change) is induced in the polymer substrate. Additionally, high‐frequency diode operation up to 1 GHz is demonstrated for devices with an active area of 10 000 µm² at 0 V bias. These devices can serve as building blocks for high‐frequency rectifying circuits and in more sophisticated arrangements toward applications in, for example, wireless bioelectronic implants.  相似文献   

    

Liang Hu  Yu Wan  Qiang Zhang  Michael J. Serpe 《Advanced functional materials》2020,30(2)

A common behavior found in nature is the ability of plants and animals to naturally respond to their surroundings through actuation. Stimuli‐responsive polymers exhibit the same ability to naturally respond to changes in their environment, although manipulating them in a manner that allows their responses to be harnessed to do work via actuation is far from trivial. In this Review, examples that use temperature, pH, light, and electric field (and other) stimulation for actuation are highlighted. The actuation can result in materials that can be used to grip, lift, and move objects as well as for their own movement. As tremendous progress is being made in this research area, it is hard to imagine a future without these materials impacting lives in some way.  相似文献   

Stimuli‐Responsive Actuation: Harnessing the Power of Stimuli‐Responsive Polymers for Actuation (Adv. Funct. Mater. 2/2020)     

Liang Hu  Yu Wan  Qiang Zhang  Michael J. Serpe 《Advanced functional materials》2020,30(2)

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Guangxi Huang  Yuqing Jiang  Sifen Yang  Bing Shi Li  Ben Zhong Tang 《Advanced functional materials》2019,29(16)

Multi‐stimuli‐responsive fluorescent molecule tetraphenylethylene (TPE) derivative 1 is synthesized, which contains a TPE skeleton and peripheries of two methoxyl groups and one carboxyl group. It shows a typical aggregation‐induced emission behavior and also exhibits fluorescence responses to pH change and amine vapors, and multicolored mechanochromic properties. The emission of 1 can be reversibly switched among blue (1p‐f, 462 nm, Φ_f = 7.4%), bright cyan (1p‐h, 482 nm, Φ_f = 82.3%), and yellow (1p‐g, 496 nm, Φ_f = 10.5%) with high contrast through solvent fuming, heating, or grinding. Molecule 1 occurs in four crystalline states (1c‐a, 1c‐b, 1c‐c, and 1c‐d) after crystallization from different solvents. The multicolored mechanochromic property is related to the different interactions and packing modes of molecules in the crystals. The crystals with weak fluorescent emission have characteristic porous structures and corresponding intensive XRD diffraction peaks, which are absent in the crystal with intensive fluorescent emission. The porous structures are critical for the fluorescence intensity of the molecules. Upon heating, the porous structures of crystals are damaged and fluorescence is significantly enhanced.  相似文献   

    

Pradyot Koley  Animesh Pramanik 《Advanced functional materials》2011,21(21):4126-4136

The small‐sized molecules that have been developed from single hydrophobic amino acids (Phe, Trp, Tyr and Leu) by suitably protecting the –NH₂ and –CO₂H groups generate diverse nanoscopic structures – such as nanorods, nanofibrils, nanotubes, and nanovesicles – depending upon the protection parameters and solvent polarity. The vesicular structures get disrupted in the presence of various salts, such as KCl, CaCl₂, (NH₄)₂SO₄ and N(n‐Bu)₄Br. Insertion of unnatural (o/m/p)‐aminobenzoic acids as a protecting group and the lack of conventional peptide bonds in the molecules give the nanostructures proteolytic stability. The nanostructures also show significant thermal stability along with a morphological transformation upon heat treatment. Our in vitro studies reveal that the addition of micromolar concentration “curcumin” significantly reduces the formation of amyloid‐like fibrils. These diverse nanostructures are used as a template for fabricating silver nanoparticles on their outer surfaces as well as in the inner part, followed by calcination in air which helps to obtain a 1D silver nanostructure. Furthermore, the nanovesicles are observed to encapsulate a potent drug (curcumin) and other biologically important molecules, which could be released through salt‐triggered disruption of vesicles.  相似文献