Biopolymer Nanoscale Assemblies as Building Blocks for New Materials: A Review

Pei, Ying; Wang, Lu; Tang, Keyong; Kaplan, David L.

doi:10.1002/adfm.202008552

Cited by 83 publications

(57 citation statements)

References 395 publications

(271 reference statements)

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“…A few biotemplates including the proteins in tobacco mosaic virus, ferritin, [19] and butterfly wings [20] have been successfully exploited to prepare porous TiO 2 thin films. Being engineered from the most abundant biopolymers, [21] nanocellulose represents another type of biotemplates, [22] which typically includes cellulose nanocrystals (CNCs), cellulose nanofibrils (CNFs), and bacterial cellulose. [23] Although CNCs [24] and bacterial cellulose [25] have demonstrated promising possibilities for fabricating 3D templates of TiO 2 thin films, the progress over CNF-templated TiO 2 thin films is still very limited.…”

Section: Surface-enhancedmentioning

confidence: 99%

Biopolymer‐Templated Deposition of Ordered and Polymorph Titanium Dioxide Thin Films for Improved Surface‐Enhanced Raman Scattering Sensitivity

Chen

Betker

Harder

et al. 2021

Adv Funct Materials

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Titanium dioxide (TiO 2 ) is an excellent candidate material for semiconductor metal oxide-based substrates for surface-enhanced Raman scattering (SERS). Biotemplated fabrication of TiO 2 thin films with a 3D network is a promising route for effectively transferring the morphology and ordering of the template into the TiO 2 layer. The control over the crystallinity of TiO 2 remains a challenge due to the low thermal stability of biopolymers. Here is reported a novel strategy of the cellulose nanofibril (CNF)-directed assembly of TiO 2 /CNF thin films with tailored morphology and crystallinity as SERS substrates. Polymorphous TiO 2 /CNF thin films with well-defined morphology are obtained by combining atomic layer deposition and thermal annealing. A high enhancement factor of 1.79 × 10 6 in terms of semiconductor metal oxide nanomaterial (SMON)-based SERS substrates is obtained from the annealed TiO 2 /CNF thin films with a TiO 2 layer thickness of 10 nm fabricated on indium tin oxide (ITO), when probed by 4-mercaptobenzoic acid molecules. Common SERS probes down to 10 nm can be detected on these TiO 2 /CNF substrates, indicating superior sensitivity of TiO 2 /CNF thin films among SMON SERS substrates. This improvement in SERS sensitivity is realized through a cooperative modulation of the template morphology of the CNF network and the crystalline state of TiO 2 .

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Section: Surface-enhancedmentioning

confidence: 99%

Biopolymer‐Templated Deposition of Ordered and Polymorph Titanium Dioxide Thin Films for Improved Surface‐Enhanced Raman Scattering Sensitivity

Chen

Betker

Harder

et al. 2021

Adv Funct Materials

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“…Collagen is also an important technical material with various potential applications in tissue engineering, regeneration medicine, and implantable medical devices (23)(24)(25)(26). For instance, collagenbased membranes have been used in periodontal and implant therapy in clinic to promote the growth of specific types of cells.…”

Section: Introductionmentioning

confidence: 99%

Electro-assembly of a dynamically adaptive molten fibril state for collagen

Miao

Wan

et al. 2022

Sci. Adv.

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Collagen is a biological building block that is hierarchically assembled into diverse morphological structures that, in some cases, is dynamically adaptive in response to external cues and in other cases forms static terminal structures. Technically, there is limited capabilities to guide the emergence of collagen’s hierarchical organization to recapitulate the richness of biological structure and function. Here, we report an electro-assembly pathway to create a dynamically adaptive intermediate molten fibril state for collagen. Structurally, this intermediate state is composed of partially aligned and reversibly associating fibrils with limited hierarchical structure. These molten fibrils can be reversibly reconfigured to offer dynamic properties such as stimuli-stiffening, stimuli-contracting, self-healing, and self-shaping. Also, molten fibrils can be guided to further assemble to recapitulate the characteristic hierarchical structural features of native collagen (e.g., aligned fibers with D-banding). We envision that the electro-assembly of collagen fibrils will provide previously unidentified opportunities for tailored collagen-based biomedical materials.

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“…This topic has been extensively reviewed elsewhere. [19,20,212] The direct thermoplastic molding of pure chitin or its derivatives without plasticizers has not been reported, while the chemical modification of chitin through acylation has been extensively explored to improve processibility. [213] However, it remains challenging to thermally mold acylated chitin alone due to the closeness of the decomposition and flow temperatures, resulting in a narrow processing window for thermoplastic molding.…”

Section: Chitin Processingmentioning

confidence: 99%

“…Alternatively, solution-based methods, [15][16][17][18] where biopolymers dissolve at the molecular level, have traditionally been used for fibrous biopolymer processing to overcome or embrace the inherent structural stability of these native materials. The unique hierarchical organization of their fibrous structures prompts the use of fibrillation-based methods more recently developed for processing, [19,20] where the native building blocks of the fibrous biopolymers are retained during processing. This gap between synthetic plastic processing (thermal) and fibrous biopolymer (solution and fibrillation based) processing approaches invariably results in major gaps in process utility, complexity, costs, and consistency in polymer outcome; thermoplastics are preferred.…”

Section: Introductionmentioning

confidence: 99%

Fiber‐Based Biopolymer Processing as a Route toward Sustainability

Shi

et al. 2021

Advanced Materials

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nomic losses, and a reduction in natural fossil resources. With the current recycling infrastructure, only 14% of current plastic-packaging waste is collected, and even with this recycling, 4% is lost during the process and 8% is redirected for the fabrication of lower-value applications. [5] The long degradation half-lives of synthetic plastics, which break down in the environment over decades or centuries, is the central problem of sustainability. [4,6] Therefore, seeking sustainable and biodegradable alternatives to synthetic plastics have become a pressing task. Developing biodegradable products from renewable resources (e.g., natural biopolymers) represents the best option by fitting material design, production, use, and disposal into a circular materials lifecycle approach (Figure 1b). [7] Instead of losing fossil fuel resources into landfills and causing environmental burdens, natural biopolymers offer options for composting/degradation, thus, recycling the carbon back to environmental cycles for the regeneration of feedstocks. Besides being sustainable and biodegradable, fibrous structural biopolymers from plants (e.g., cellulose) and animals (e.g., silk, chitin) have unique hierarchical structures, with structural integrity, flexibility, and toughness. Therefore, fibrous structural biopolymers represent a class of material that could help to supplement or replace some conventional synthetic plastics. Additionally, the inherent biocompatibility of most natural biopolymers makes them important candidates for added-value applications, such as in regenerative medicine, drug delivery, and tissueimplantable devices. Among these natural biopolymers, cellulose, chitin, and silk fibroin represent the most abundant and investigated biopolymers in the categories of polysaccharides and proteins (Table 1).The first step in this progression toward sustainability is to process fibrous biopolymers into material formats suitable for targeted applications. The sophisticated hierarchical structure of fibrous biopolymers, which consists of well-organized structural features from molecular to nano-to macroscopic length scales, employ extensive hydrogen bonding networks embedded within semicrystalline structures across all structural levels. This structural stability endows fibrous biopolymers with exceptional mechanical properties, but also generates challenges with the direct processing of the fibrous materials into useful material formats via traditional thermal processing methods that are widely used for synthetic polymer processing Some of the most abundant biomass on earth is sequestered in fibrous biopolymers like cellulose, chitin, and silk. These types of natural materials offer unique and striking mechanical and functional features that have driven strong interest in their utility for a range of applications, while also matching environmental sustainability needs. However, these material systems are challenging to process in cost-competitive ways to compete with synthetic plastics due to the limited options for ther...

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Biopolymer Nanoscale Assemblies as Building Blocks for New Materials: A Review

Cited by 83 publications

References 395 publications

Biopolymer‐Templated Deposition of Ordered and Polymorph Titanium Dioxide Thin Films for Improved Surface‐Enhanced Raman Scattering Sensitivity

Biopolymer‐Templated Deposition of Ordered and Polymorph Titanium Dioxide Thin Films for Improved Surface‐Enhanced Raman Scattering Sensitivity

Electro-assembly of a dynamically adaptive molten fibril state for collagen

Fiber‐Based Biopolymer Processing as a Route toward Sustainability

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