Protein-based materials compositions

To extend the application area of silk proteins-based materials, blending the fibroin with other natural macromolecules and synthetic polymers, or even manufacturing composites with silk fibers are a few of the possible strategies. 

Due to the struggle to survive under circumstances of limited food supply, organisms evolve to use the most efficient mechanism available to their composition. The most efficient mechanism available to the proteins that sustain Life would seem to be the apolar-polar repulsive free energy of hydration as observed for the inverse temperature transitions for hydrophobic association. The efficiency of designed elastic-contractile protein-based machines and a number of additional properties make designed protein-based materials of substantial promise for the marketplace of the future. 

Protein-based polymers have the potential to surpass the polyesters and other polymers because they can be directly produced in microorganisms and plants by recombinant DNA technology resulting in the capacity for diverse and precisely controlled composition and sequence. This is not possible with any other polymer, and it increases range of properties and the numbers of applications. Remarkably, with the proper design of composition, protein-based materials can be thermoplastics, melting at temperatures as much as 100°C below their decomposition temperatures. Therefore, they can be molded, extruded, or drawn into shapes as desired. Aspects of protein-based materials as plastics is also considered below. 

The initial preparation of protein-based polymers utilized solution and solid phase peptide chemistry. This made possible the preparation of more than 1,000 polymer compositions. As discussed in Chapter 5, these compositions were studied for determination of their basic properties, for the development of the set of phenomenological axioms for protein engineering and function, and for the demonstration of the basic mechanism that underlies function. In short, it is the chemical synthesis that has allowed development of much of the basic science and the demonstration of the potential of protein-based materials in a timely manner. Mostly because of the historical relevance, but also because of the unique contributions of chemical synthesis to arriving at satisfactory purification of microbially prepared protein-based polymers, a brief description of the chemical synthesis of protein-based polymers is given below. 

ProLastin polymers are a family of protein-based materials w hose resorption rate in vivo can be controlled by adjusting the sequence and not just the composition of the polymer (Cappello et al, 1995). These adjustments can be made so as to cause little change in the formulation characteristics of the materials, their physical forms, or their mechanical properties. They have good mechanical integrity with no need for chemical crosslinking. They degrade by enzymatic proteolysis and are presumed to resorb by surface erosion. Their breakdowm products are peptides or amino acids w hich are electroneutral at physiological pH and cause no undue inflammation or tissue response. 

Soy protein-based green composites are not only applied as an environmental friendly material in the fields of adhesives (Kumar et al. 2002), plastics (Kumar et al. 2011), and textile fibers (Kobayashi et al. 2014), but also as biodegradable membranes (Mamthi et al. 2014). Furthermore, the nutritional and health benefits of soy protein draw attention to the application in the field of biomedical materials (Silva et al. 2014), such as tissue engineering scaffolds (Chien and Shah 2012),... 

The barrier properties of protein materials depend on the nature and density of the macromolecular network, and more particularly on the proportion and distribution of nonpolar amino acids relative to polar amino acids [11,27], The protein composition and structural organisation of the network enables some chemical groups to remain free, which means that they are sites of potential interactions with permeating molecules. Generally for protein-based materials, most free hydrophilic groups are able to interact with water vapour and permit water transfer phenomena, to the detriment of hydrophobic gas transfers (e.g., nitrogen and O2). 

The mechanical properties of protein-based materials closely depend on the plasticizer content, temperature and ambient relative humidity (16,34,35). At constant temperature and composition, an increase in relative humidity leads to a major change in the material properties, with a sharp drop in mechanical strength and a concomitant sharp rise in distortion. These modifications occur when the Tg of the material is surpassed (Figure 1). These variations can be reduced by implementing crosslinking treatments (physical or chemical) or using high cellulose or mineral loads (22). 

Nakamura, R, Netravali, A.N., Morgan, A.B., Nyden, M.R., Gilman, J.W., 2013. Effect of halloysite nanotubes on mechanical properties and flammability of soy protein based green composites. Fire and Materials 37, 75—90. 

Given the actual scenario, one can state that the emerging field of nanotechnology represents new effort to exploit new materials as well as new technologies in the development of efficient and low-cost solar cells. In fact, the technological capabilities to manipulate matter under controlled conditions in order to assemble complex supramolecular structures within the range of 100 nm could lead to innovative devices (nano-devices) based on unconventional photovoltaic materials, namely, conducting polymers, fuUerenes, biopolymers (photosensitive proteins), and related composites. 

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