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1. Rheological Characterization of Alginate Based Hydrogels for Tissue Engineering

   https://doi.org/10.1557/adv.2017.8  

   Duan, Pengfei; Kandemir, Nehir; Wang, Jiajun; Chen, Jinju (January 2017, MRS Advances)

   ABSTRACT Hydrogels have been widely used in many applications from tissue engineering to drug delivery systems. For both tissue engineering and drug delivery, the mechanical properties are important because they would affect cell-materials interactions and injectability of drugs encapsulated in hydrogel carriers. Therefore, it is important to study the mechanical properties of these hydrogels, particularly at physiological temperature (37°C). This study adopted strain sweep and frequency sweep rotational rheological tests to investigate the rheological characteristics of various tissue engineering relevant hydrogels with different concentrations at 37°C. These hydrogels include alginate, RGD-alginate, and copolymerized collagen/alginate/fibrin. It has revealed that the addition of RGD has negligible effect on the elastic modulus and viscosity of alginate. Alginate gels have demonstrated shear thinning behavior which indicates that they are suitable candidates as carriers for cells or drug delivery. The addition of collagen and fibrin would reinforce the mechanical properties of alginate which makes it a strong scaffold material. 

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2. Modifying Naturally Occurring, Nonmammalian-Sourced Biopolymers for Biomedical Applications

   https://doi.org/10.1021/acsbiomaterials.4c00689  

   Shirk, Bryce D; Heichel, Danielle L; Eccles, Lauren E; Rodgers, Liam I; Lateef, Ali H; Burke, Kelly A; Stoppel, Whitney L (October 2024, ACS Biomaterials Science & Engineering)

   Natural biopolymers have a rich history, with many uses across the fields of healthcare and medicine, including formulations for wound dressings, surgical implants, tissue culture substrates, and drug delivery vehicles. Yet, synthetic-based materials have been more successful in translation due to precise control and regulation achievable during manufacturing. However, there is a renewed interest in natural biopolymers, which offer a diverse landscape of architecture, sustainable sourcing, functional groups, and properties that synthetic counterparts cannot fully replicate as processing and sourcing of these materials has improved. Proteins and polysaccharides derived from various sources (crustaceans, plants, insects, etc.) are highlighted in this review. We discuss the common types of polysaccharide and protein biopolymers used in healthcare and medicine, highlighting methods and strategies to alter structures and intra- and interchain interactions to engineer specific functions, products, or materials. We focus on biopolymers obtained from natural, nonmammalian sources, including silk fibroins, alginates, chitosans, chitins, mucins, keratins, and resilins, while discussing strategies to improve upon their innate properties and sourcing standardization to expand their clinical uses and relevance. Emphasis will be placed on methods that preserve the structural integrity and native biological functions of the biopolymers and their makers. We will conclude by discussing the untapped potential of new technologies to manipulate native biopolymers while controlling their secondary and tertiary structures, offering a perspective on advancing biopolymer utility in novel applications within biomedical engineering, advanced manufacturing, and tissue engineering. 

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3. Smart Polymers for Microscale Machines

   https://doi.org/10.1002/adfm.202007125  

   Tan, Liyuan; Davis, Aaron_C; Cappelleri, David_J (December 2020, Advanced Functional Materials)

   Abstract Microscale machines are able to perform a number of tasks like micromanipulation, drug‐delivery, and noninvasive surgery. In particular, microscale polymer machines that can perform intelligent work for manipulation or transport, adaptive locomotion, or sensing are in‐demand. To achieve this goal, shape‐morphing smart polymers like hydrogels, liquid crystalline polymers, and other smart polymers are of great interest. Structures fabricated by these materials undergo mechanical motion under stimulation such as temperature, pH, light, and so on. The use of these materials renders microscale machines that undergo complex stimuli‐responsive transformation such as from planar to 3D by combining spatial design like introducing in‐plane or out‐plane differences. During the past decade, many techniques have been developed or adopted for fabricating structures with smart polymers including microfabrication methods and the well‐known milestone of 4D printing, starting in 2013. In this review, the existing or potential active smart polymers that could be used to fabricate active microscale machines to accomplish complex tasks are summarized. 

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4. Tailoring the formation and stability of self-assembled structures from precisely engineered intrinsically disordered protein polymers: A comprehensive review

   https://doi.org/10.1016/j.giant.2023.100158  

   Doole, Fathima T.; Camp, Christopher P.; Kim, Minkyu (June 2023, Giant)

   Intrinsically disordered proteins (IDPs) are a class of proteins that lack stable three-dimensional structures. Despite their natural tendency to be disordered, precise modulations of molecular parameters (e.g., sequence, length) through biomolecular engineering tools and control of environmental conditions tailor the formation of dynamic self-assembled structures. In addition to designing structures that respond to external stimuli for specific biotechnological applications (e.g., biosensors), other applications require stable structures (e.g., engineered tissues, drug delivery vehicles) that resist unintended changes and disassembly across various environmental conditions, such as different concentrations and temperatures. This review provides a comprehensive understanding of the design and engineering principles that govern the self-assembly of biosynthetic IDPs and their stability. Specifically, elastin-like polypeptides (ELPs) are highlighted as a prominent example of biosynthetically designed, thermoresponsive IDPs. Examples include ELPs that form various self-assembled structures by themselves as ELP homopolymers or diblock copolymers, ELPs combined with other IDPs in diblock copolymers, and ELP-based polymer hybrids containing functional (bio)molecules. It is anticipated that the efforts to enhance the stability of self-assembled structures through the precise engineering of IDP-based polymers have expanded the potential for diverse biotechnological applications in tissue engineering, drug delivery, diagnostic assays, and biomedicine. 

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5. 3D Structuring of Magnetoelastomers for Anisotropic Actuation Properties

   Atescan, Yagmur; Yamamoto, Namiko. (January 2020, AIAA paper)

   Smart structures with actuation function are desired for aerospace applications, including morphing airfoils, deployable structures and more. While shape memory alloys and piezoelectric ceramics and polymers are currently a popular smart material options for such applications, magnetoelastomers (MEs) can be uniquely actuated with application of non-contact magnetic field. Magnetoelastomers (MEs), composite materials made of magnetic particles and soft, non-magnetic matrix, can potentially contribute to such smart structures as a light-weight, smart material option with large strain change, fast response time (milliseconds) and anisotropic actuation properties. Other than aerospace applications, MEs, as soft actuators, have been investigated for flexible electronics, soft robotics, and biomedical applications. Anisotropic actuation properties of MEs can be controlled with particle organization within the elastomer. To provide this control, parametric studies on fabrication of MEs need to be performed. This study presents experimental work on nanoparticle organization within MEs using uniaxial, biaxial and triaxial magnetic fields and on the structure-property relationships of MEs. Iron oxide nanoparticles were used as a model nanofillers, and their surfaces were treated with silane coupling agent to improve dispersion and suspension within a polydimethylsiloxane (PDMS) elastomer. The fabricated MEs were inspected using microCT, and their anisotropic susceptibilities are being measured. 

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