Abstract
Eri silkworm cocoons (E cocoons) are natural composite biopolymers formed by continuous twin silk filaments (fibroin) bonded by sericin. As a kind of wild species, E cocoons have characteristics different from those of Bombyx mori cocoons (B cocoons). E cocoons have an obvious multilayer (5–9 layers) structure with an eclosion hole at one end and several air gaps between the layers, which can be classified into three categories—cocoon coat, cocoon layer, and cocoon lining—with varying performance indexes. There is a significant secondary fracture phenomenon during the tensile process, which is attributed to the high modulus of the cocoon lining and its dense structure. Air gaps provide cocoons with distinct multistage moisture transmission processes, which form a good moisture buffer effect. Temperature change inside cocoons is evidently slower than that outside, which indicates that cocoons also have an obvious temperature damping capability. The eclosion hole does not have much effect on heat preservation of E cocoons. The high sericin content of the cocoon coat, as well as the excellent ultraviolet absorption and antimicrobial abilities of sericin, allows E cocoons to effectively prevent ultraviolet rays and microorganisms from invading pupae. The ultraviolet protection factor (UPF) of the E cocoon before and after degumming were found to be 17.8% and 9.7%, respectively, which were higher than those of the B cocoon (15.3% and 4.4%, respectively), indicating that sericin has a great impact on anti-UV performance. In the cocoon structure, the outer layer of the cocoon has 50% higher content than the inner layer, and the E cocoon shows stronger protection ability than the B cocoon. Understanding the relationship between the structure, property, and function of E cocoons will provide bioinspiration and methods for designing new composites.
Highlights
Cocoon is a type of unique and important biopolymer composite in nature with excellent microstructure and ecological functions
The ultraviolet protection factor (UPF) of the E cocoon before and after degumming were found to be 17.8% and 9.7%, respectively, which were higher than those of the B cocoon (15.3% and 4.4%, respectively), indicating that sericin has a great impact on anti-UV performance
The external shapes of the E cocoon were not uniform, Figure 4c shows that the shape of cavity of the cocoon was regular and similar to an elliptical shape after stripping the cocoon coat and partial cocoon layers, and the end of the eclosion hole was radiative like a crater
Summary
Cocoon is a type of unique and important biopolymer composite in nature with excellent microstructure and ecological functions. The process of silk spinning and cocoon construction has undergone long-term natural selection and extensive evolution. Cocoons are thin and lightweight, they can protect silkworms from various invasions in nature and provide a good place for silkworm metabolism [2,3,4]. Silk from Bombyx mori (mulberry silkworm) has been the most commonly used silk for centuries [5]. Wild varieties, such as eri silkworms, have been partially domesticated for commercial applications [3,4,6]. Eri silkworms are the third largest silkworms in the Polymers 2020, 12, 2701; doi:10.3390/polym12112701 www.mdpi.com/journal/polymers
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