Development and evaluation of edible films based on cassava starch, whey protein, and bees wax

Cortés, Misael; Yépez, Camilo Villegas; González, Jesús Humberto Gil; Fonseca, Pablo Emilio Rodríguez; Ortega‐Toro, Rodrigo

doi:10.1016/j.heliyon.2020.e04884

Cited by 45 publications

(23 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…The similarities in the whiteness values of the biofilms may be attributed to the starch extraction process, [32,33] which may remove the pigment or other light-absorbing substances present in potato tubers and arracacha roots. [34][35][36] Whiteness values between 87 and 89.8 were previously obtained in biofilms made from 2-3% olluco starch. [4] Similarly, whiteness values between 79.01 and 83.28 were obtained in biofilms made with 5% potato starch reinforced with zein/olive oil nanoparticles.…”

Section: Optimization Of Variables Using Response Surface Methodologymentioning

confidence: 99%

Development and Optimization of Biofilms Made from Potato or Arracacha Starch

et al. 2021

View full text Add to dashboard Cite

Arracacha starch and potato starch are alternatives to synthetic polymers as starting materials for the production of biofilms. Herein, we determined the optimal concentrations of glycerol and potato or arracacha starch to obtain biofilms with high whiteness, transparency value (TV), and elastic modulus (E). Central composite design with the response surface methodology and desirability function are used to optimize the concentration of starch and glycerol. The biofilms are formed by the casting method using gelatinized starch suspensions (3-5%) mixed with glycerol (1-3%). The solubility and swelling power differences of the potato and arracacha starches indicated differences in the starch structures, which affected the properties of the biofilms. The potato and arracacha biofilms with the same starch and glycerol concentrations exhibited different TV and E. Linear effects, quadratics, and the interaction of the starch and glycerol have significant effects on the whiteness, TV, and E of the potato and arracacha biofilms (p < 0.05). The coefficient of variation for the obtained models is >0.98%. The optimal conditions determined using the desirability function are 5% starch and 1.02% glycerol for potato biofilms and 5% starch and 1% glycerol for arracacha starch biofilms.

show abstract

Section: Optimization Of Variables Using Response Surface Methodologymentioning

confidence: 99%

Development and Optimization of Biofilms Made from Potato or Arracacha Starch

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Most reports on the formation and properties of biopolymers films focus on their use as edible films (being incorporated in the form of biodegradable films) [121][122][123][124]. Biopolymers exhibit relatively weak mechanical and barrier properties, which are currently limited to industrial usages.…”

Section: Natural Biopolymersmentioning

confidence: 99%

Employing Nanosilver, Nanocopper, and Nanoclays in Food Packaging Production: A Systematic Review

et al. 2021

View full text Add to dashboard Cite

Over the past decade, there has been an increasing demand for “ready-to-cook” and “ready-to-eat” foods, encouraging food producers, food suppliers, and food scientists to package foods with minimal processing and loss of nutrients during food processing. Following the increasing trend in the customer’s demands for minimally processed foodstuffs, this underscores the importance of promising interests toward industrial applications of novel and practical approaches in food. Along with substantial progress in the emergence of “nanoscience”, which has turned into the call of the century, the efficacy of conventional packaging has faded away. Accordingly, there is a wide range of new types of packaging, including electronic packaging machines, flexible packaging, sterile packaging, metal containers, aluminum foil, and flexographic printing. Hence, it has been demonstrated that these novel approaches can economically improve food safety and quality, decrease the microbial load of foodborne pathogens, and reduce food spoilage. This review study provides a comprehensive overview of the most common chemical or natural nanocomposites used in food packaging that can extend food shelf life, safety and quality. Finally, we discuss applying materials in the production of active and intelligent food packaging nanocomposite, synthesis of nanomaterial, and their effects on human health.

show abstract

“…Pendapat ini diperkuat hasil penelitian Martins et al (2020), yaitu adanya kombinasi polisakarida dan protein dengan rasio polisakarida lebih banyak dari protein dapat meminimalkan bobot susut yang terjadi selama proses termal dengan pengeringan berlangsung. Adanya kombinasi kasein dan tapioka dapat meningkatkan viskositas yang berimplikasi pada meningkatnya ketebalan (Cortés-Rodríguez et al, 2020;Lindriati et al, 2014). Adanya kombinasi antara kasein dan tapioka dapat menjadi sarana untuk meminimalkan biaya produksi pembuatan bioplastik dan juga memungkinkan mengatasi kekurangan karakteristik bioplastik yang berasal hanya dari polisakarida ataupun protein.…”

Section: Pendahuluanunclassified

“…Hasil penelitian Cortés-Rodríguez et al ( 2020) menunjukkan bahwa film dengan kombinasi antara protein dan polisakarida meningkatkan ketebalan film, yang terdiri dari polisakarida saja. Cortés-Rodríguez et al (2020) berpendapat bahwa adanya perbedaan ketebalan film, yang hanya terdiri pati saja, dengan yang dikombinasi pati dan whey, berbeda karena dipengaruh laju pengeringan yang berbeda pada biokomposit, interaksi gugus hidrofilik bahan baku pada formulasi film, dan karena distribusi padatan yang tidak homogen per cm 2 pada permukaan film selama pengeringan. Skurtys et al (2011) menyatakan semakin tebal bioplastik dalam keadaan normal (tidak memiliki porisitas dan bersifat higroskopis), berimplikasi semakin baiknya kemampuannya dalam menurunkan nilai pertukaran gas seperti O 2 dan CO 2 .…”

Section: Ketebalanunclassified

Karakteristik fisis bioplastik yang dibuat dari kombinasi pati tapioka dan kasein susu apkir

Nugrahanto¹,

Kurniawati²,

Erwanto

2021

MKKP

View full text Add to dashboard Cite

This study aimed to develop bioplastic from a combination of tapioca starch and casein, as well as to determine the physical characteristics, such as thickness, density, light transmittance, and opacity. The composition of the bioplastic was made from two types of casein, namely commercial casein and rejected milk casein, with a ratio of tapioca starch and casein consisting of 4 treatment groups (4:0, 3:1, 2.5:1.5, 2:2). Each treatment was repeated 6 times. The physical characteristics data obtained were analyzed using a two-way ANOVA completely randomized design variance analysis. If there is a difference, it is continued with the Duncan multiple range test (DMRT). The results showed that the ratio of starch and casein had a very significant effect on all test parameters (P<0.01). An increase in commercial casein (CC) and rejected milk casein (EMC) increased thickness and opacity, while density and light transmittance decreased. Based on the research, bioplastic can be made with a combination of different ratios of tapioca starch and casein types with the best result were at a ratio of 2:2 which produced a thickness of 0.29 mm, light transmittance of 20.03%, opacity of 2.51%, while the density had the smallest value at 0.15 gr/cm 3 . In conclusion, rejected milk casein could be used as biomaterial to make bioplastic combined with tapioca starch.

show abstract

Development and evaluation of edible films based on cassava starch, whey protein, and bees wax

Cited by 45 publications

References 39 publications

Development and Optimization of Biofilms Made from Potato or Arracacha Starch

Development and Optimization of Biofilms Made from Potato or Arracacha Starch

Employing Nanosilver, Nanocopper, and Nanoclays in Food Packaging Production: A Systematic Review

Karakteristik fisis bioplastik yang dibuat dari kombinasi pati tapioka dan kasein susu apkir

Contact Info

Product

Resources

About