Viridiana Tejada-Ortigoza, Luis Eduardo Garcia-Amezquita, Diana E. Leyva-Daniel, Celeste C. Ibarra-Herrera, Genaro G. Amador-Espejo, Jorge Welti-Chanes
{"title":"可食用昆虫面粉的吸附等温线:数学建模和滞后现象","authors":"Viridiana Tejada-Ortigoza, Luis Eduardo Garcia-Amezquita, Diana E. Leyva-Daniel, Celeste C. Ibarra-Herrera, Genaro G. Amador-Espejo, Jorge Welti-Chanes","doi":"10.1007/s13197-024-06063-4","DOIUrl":null,"url":null,"abstract":"<p>The interest in insects as food has increased in the latest years. Their use as low-moisture food ingredients has led to study their behavior during storage. The moisture sorption isotherms of Mexican edible insect᾽s flours (cricket-<i>Acheta domesticus</i>, mealworm-<i>Tenebrio molitor</i>, superworm-<i>Zophoba morio</i>, grasshopper-<i>Sphenarium purpurascens</i>, escamol-<i>Liometopum apiculatum</i>) were determined through the dynamic method. Mathematical models were used for fitting the adsorption and desorption curves and Akaike Information Criteria (AIC<sub>i</sub>) was used to evaluate their performance. Hysteresis was determined quantitatively. The samples presented a BET Type II behavior; for adsorption and desorption, GAB and Peleg᾽s were the models with the best fitting according to the AIC<sub>i</sub>, respectively. GAB (R<sup>2</sup> ≥ 0.991) was used to determine M<sub>0</sub>, with values ranging between 4.14 (superworm-adsorption) and 6.40 gH<sub>2</sub>O/100 g d.s. (mealworm-desorption). Also, escamol desorption GAB C value was up to 12.6 times higher than the one observed in adsorption, being this one the less stable sample. The lowest areas of hysteresis were observed for cricket (1.32) and grasshopper (1.63), resulting in stable materials; this agreed with the C values of GAB. More studies are needed for the establishment of processing conditions of insects, information required for local producers to increase the insect market in Mexico and in the world.</p>","PeriodicalId":632,"journal":{"name":"Journal of Food Science and Technology","volume":null,"pages":null},"PeriodicalIF":2.7010,"publicationDate":"2024-08-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Sorption isotherms of edible insect’s flours: mathematical modeling and hysteresis\",\"authors\":\"Viridiana Tejada-Ortigoza, Luis Eduardo Garcia-Amezquita, Diana E. Leyva-Daniel, Celeste C. Ibarra-Herrera, Genaro G. Amador-Espejo, Jorge Welti-Chanes\",\"doi\":\"10.1007/s13197-024-06063-4\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>The interest in insects as food has increased in the latest years. Their use as low-moisture food ingredients has led to study their behavior during storage. The moisture sorption isotherms of Mexican edible insect᾽s flours (cricket-<i>Acheta domesticus</i>, mealworm-<i>Tenebrio molitor</i>, superworm-<i>Zophoba morio</i>, grasshopper-<i>Sphenarium purpurascens</i>, escamol-<i>Liometopum apiculatum</i>) were determined through the dynamic method. Mathematical models were used for fitting the adsorption and desorption curves and Akaike Information Criteria (AIC<sub>i</sub>) was used to evaluate their performance. Hysteresis was determined quantitatively. The samples presented a BET Type II behavior; for adsorption and desorption, GAB and Peleg᾽s were the models with the best fitting according to the AIC<sub>i</sub>, respectively. GAB (R<sup>2</sup> ≥ 0.991) was used to determine M<sub>0</sub>, with values ranging between 4.14 (superworm-adsorption) and 6.40 gH<sub>2</sub>O/100 g d.s. (mealworm-desorption). Also, escamol desorption GAB C value was up to 12.6 times higher than the one observed in adsorption, being this one the less stable sample. The lowest areas of hysteresis were observed for cricket (1.32) and grasshopper (1.63), resulting in stable materials; this agreed with the C values of GAB. 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引用次数: 0
摘要
近年来,人们对昆虫作为食品的兴趣与日俱增。昆虫作为低水分食品配料的使用促使人们开始研究它们在贮藏过程中的行为。通过动态法测定了墨西哥食用昆虫(蟋蟀-Acheta domesticus、黄粉虫-Tenebrio molitor、超级虫-Zophoba morio、蚱蜢-Sphenarium purpurascens、escamol-Liometopum apiculatum)面粉的水分吸附等温线。使用数学模型拟合吸附和解吸曲线,并使用阿凯克信息标准(AICi)评估其性能。对滞后进行了定量测定。样品呈现出 BET II 型行为;根据 AICi,GAB 和 Peleg᾽s 模型分别是吸附和解吸的最佳拟合模型。GAB(R2 ≥ 0.991)用于确定 M0,其值介于 4.14(超级蠕虫-吸附)和 6.40 gH2O/100 g d.s.(黄粉虫-解吸)之间。此外,escamol 解吸附 GAB C 值比吸附值高 12.6 倍,是稳定性较差的样品。蟋蟀(1.32)和蚱蜢(1.63)的滞后面积最小,因此是稳定的材料;这与 GAB 的 C 值一致。需要进行更多的研究,以确定昆虫的加工条件,这是当地生产商增加墨西哥和世界昆虫市场所需的信息。
Sorption isotherms of edible insect’s flours: mathematical modeling and hysteresis
The interest in insects as food has increased in the latest years. Their use as low-moisture food ingredients has led to study their behavior during storage. The moisture sorption isotherms of Mexican edible insect᾽s flours (cricket-Acheta domesticus, mealworm-Tenebrio molitor, superworm-Zophoba morio, grasshopper-Sphenarium purpurascens, escamol-Liometopum apiculatum) were determined through the dynamic method. Mathematical models were used for fitting the adsorption and desorption curves and Akaike Information Criteria (AICi) was used to evaluate their performance. Hysteresis was determined quantitatively. The samples presented a BET Type II behavior; for adsorption and desorption, GAB and Peleg᾽s were the models with the best fitting according to the AICi, respectively. GAB (R2 ≥ 0.991) was used to determine M0, with values ranging between 4.14 (superworm-adsorption) and 6.40 gH2O/100 g d.s. (mealworm-desorption). Also, escamol desorption GAB C value was up to 12.6 times higher than the one observed in adsorption, being this one the less stable sample. The lowest areas of hysteresis were observed for cricket (1.32) and grasshopper (1.63), resulting in stable materials; this agreed with the C values of GAB. More studies are needed for the establishment of processing conditions of insects, information required for local producers to increase the insect market in Mexico and in the world.