A New Protocol for Obtaining Mucilage and Biopolymeric Ecofilms From Cacti

ABSTRACT The objective was to produce an innovative biopolymeric ecofilm, using hydrotested and reused alcohol for mucilage extraction and incorporation of calcium lactate into the film. The mucilage of Nopalea cochenillifera (L.) Salm‐Dyck was extracted with ethyl alcohol P.A. (99.8%) or reused alc...

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Published inPackaging technology & science Vol. 37; no. 5; pp. 365 - 377
Main Authors de Andrada, Lucas Vinícius Pierre, do Nascimento Souza, Jheizon Feitoza, de Sousa, Lady Daiane Costa, Brito, Andréa Monteiro Santana Silva, de Lima Silva, Ivo Diego, Vinhas, Glória Maria, da Silva, Thieres George Freire, Ferreira, Natanael Lucena, de Brito, Fred Augusto Lourêdo, do Nascimento Simões, Adriano
Format Journal Article
LanguageEnglish
Published Bognor Regis Wiley Subscription Services, Inc 01.05.2024
Subjects
Alcohol
Biopolymers
Cacti
Calcium
Carbohydrates
Electrical resistivity
Ethanol
Moisture content
Phenols
Production costs
Solubility
Tensile strength
Thermal resistance
Thermal stability
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Summary:ABSTRACT The objective was to produce an innovative biopolymeric ecofilm, using hydrotested and reused alcohol for mucilage extraction and incorporation of calcium lactate into the film. The mucilage of Nopalea cochenillifera (L.) Salm‐Dyck was extracted with ethyl alcohol P.A. (99.8%) or reused alcohol after hydrodistillation (82%). Mucilage powder was hydrated (4% w/v), glycerol at a concentration of 60% and calcium lactate (0% and 2%) were added and the emulsion was then placed in the oven for 24 h to prepare the films. The innovation of this work was the recycling of the ethanol used to extract cactus mucilage in order to prepare ecofilms, which resulted in a more environmentally friendly production process. The industrial yield of mucilage extracted using distilled ethanol (1.3%) was lower than that of P.A. alcohol (3.3%). However, the mucilage extracted using distilled ethanol had a higher concentration of carbohydrates and phenolic compounds and lower levels of Na + and K + , leading to reduced electrical conductivity. The biopolymeric ecofilm obtained was thinner (0.15 mm) and had lower solubility in water (43%) and moisture content (15%), greater transparency (12.65%) and higher tensile strength (12.91 MPa). The addition of calcium lactate in biopolymers decreased water solubility while increasing permeability and thickness. Furthermore, it enhanced the resistance and thermal stability of biopolymeric ecofilms. Thus, biopolymeric ecofilms of mucilage obtained showed potential for use in biofilms and edible coatings on fruits and vegetables, with a strong appeal for lower environmental impact and, consequently, being able to reduce manufacturing costs for the industry.
ISSN:0894-3214
1099-1522
DOI:10.1002/pts.2799