Isolation and Partial Characterization of Mexican <b><i>Oxalis tuberosa</i></b> Starch

Hernández-Lauzardo, Ana Niurka; Méndez‐Montealvo, Guadalupe; Valle, Miguel Gerardo Velázquez del; Solorza‐Feria, Javier; Bello‐Pérez, Luis A.

doi:10.1002/star.200300235

Cited by 42 publications

(36 citation statements)

References 27 publications

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“…This pattern is in agreement with the enthalpy values determined, although starch from raw maize had a higher enthalpy value, this was not different of the starch isolated from the nixtamalized sample. Similar peak temperature (72.97 • C) was obtained for commercial maize starch [20]; however, lower peak temperatures (69.5 and 71.5 • C) were determined in maize starches [21,22]. Recently, in a study with starches isolated from diverse maize varieties, reported peak temperatures between 66.1 and 71.6 • C [9], that were lower than those determined in this study.…”

Section: Thermal Analysissupporting

confidence: 62%

“…Recently, in a study with starches isolated from diverse maize varieties, reported peak temperatures between 66.1 and 71.6 • C [9], that were lower than those determined in this study. Respect to the gelatinization enthalpy, the value determined for starch from raw sample was similar to those reported previously (11.9-13.8 J/g) [20][21][22], but higher than those reported for different starches isolated from different maize varieties (9.3-12.6 J/g) [9]; however, the starch from nixtamalized sample showed lower enthalpy of gelatinization, as demonstrated in starches from nixtamalized pigmented maizes, where some starch granules lost their birefringence and low energy is necessary for the phase transition [23]. For raw starch the amylose-lipid complex was observed with a temper- ature of 102.1 • C and an enthalpy associated at this complex of 1.01 J/g.…”

Section: Thermal Analysismentioning

confidence: 96%

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Thermal and rheological properties of nixtamalized maize starch

Méndez‐Montealvo¹,

Sánchez‐Rivera²,

Paredes‐López

et al. 2006

International Journal of Biological Macromolecules

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Section: Thermal Analysissupporting

confidence: 62%

Section: Thermal Analysismentioning

confidence: 96%

Thermal and rheological properties of nixtamalized maize starch

Méndez‐Montealvo¹,

Sánchez‐Rivera²,

Paredes‐López

et al. 2006

International Journal of Biological Macromolecules

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“…The samples were analyzed in a scanning electron microscope (JEOL, JSU-5600 LV, Japon and SEI, detectors, USA) operating at 15 kV accelerating voltage as reported by Sánchez [10].…”

Section: Scanning Electron Microscope (Sem)mentioning

confidence: 99%

“…Measurements were carried out during three freeze-thaw cycle. The syneresis was calculated as the ratio between the weights of the separated liquid from gel and the gel collected after centrifugation [10].…”

Section: Freeze-thaw Stability (Fts)mentioning

confidence: 99%

Enzymatic modification of cassava starch (Corpoica M-Tai) around the pasting temperature

Salcedo¹,

Paternina-Urzola²,

Lujan-Rhenalds³

et al. 2018

DYNA

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Cassava starch variety Corpoica -TAI, was modified with a commercial α-amylase, in order to evaluate the effects of temperature, reaction time and enzyme/substrate (E/S) ratio on the degree of hydrolysis, and production of enzymatic modified starches. The modified starches presented dextrose equivalents (DE) ranging between 13 and 92%, yield (Y) between 0 and 45.5%. The Scanning electron microscope (SEM) analysis showed that the granules suffered exo-corrosion in agreement with the degree of hydrolysis. The crystallinity degree increased following modification. The granule morphology of hydrolyzed starch was different compared to the native starch. The gelatinization temperature in the residues of hydrolyzed cassava starches hydrolyzed increased with the crystallinity degree as well with the reduction in the amylose content. The native starch showed a greater setback and amylose values than hydrolyzed starches, which indicates that it is more susceptible to retrogradation or water lost (syneresis).Keywords: α-amylase; granule; crystallinity; hydrolyzed starches.Modificación enzimática de almidón de yuca (Corpoica M-Tai) alrededor de la temperatura de pasta ResumenAlmidón de yuca variedad Corpoica -TAI fue modificado con α-amilasa comercial, para evaluar el efecto de la temperatura alrededor de la temperatura de pasta, tiempo de reacción y relación enzima/sustrato (E/S) sobre el grado de hidrólisis y producción de almidones modificados enzimáticamente. Los almidones modificados presentaron equivalentes de dextrosa (DE) entre 13 y 92 %, valores de rendimiento (Y) hasta del 45.5%. El análisis Microscopia de barrido electrónico (SEM) mostró que los gránulos presentaron exo-corrosión en concordancia con el grado de hidrólisis. La cristalinidad aumento después de la modificación y la morfología del granulo fue diferente comparada con el almidón nativo. Los almidones hidrolizados presentaron un aumento en la estabilidad (breakdown) y disminución en el asentamiento (setback). La temperatura de gelatinización se incrementó con la cristalinidad y disminuyó con el contenido de amilosa. Los almidones hidrolizados fueron más susceptibles a la retrogradación o pérdida de agua (sinéresis).

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“…Gelatinization is required to produce the desired functionality (i.e., thickening and swelling) of starch in a food system; studies of isolated maize starch are abundant in the literature [49,71], since maize starch is widely used in various food systems as fillers or stabilizing agent. On the other hand, specialty starches have been produced to meet the needs of new product formulations; new raw materials are required to produce novel specialty starches such as starch-based fat replacers and RSs.…”

Section: Thermal Behaviormentioning

confidence: 99%

Starches of Some Food Crops, Changes During Processing and Their Nutraceutical Potential

Bello‐Pérez¹,

Paredes‐López

2009

Food Eng. Rev.

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Starch is a polymer widely distributed in the nature and it is the principal component of cereals, tubers, legumes, and unripe fruits. Traditionally, starch has been isolated and used as raw material in diverse food products to produce or to improve specific functionalities and nowadays novel starches from unconventional sources have gained interest due to improved or due to different physicochemical and functional characteristics, especially for new food products. Recently, the potential nutraceutical characteristics of starchy products have increased the interest on this biopolymer. In this review, we describe the physicochemical and digestibility characteristics of starch present in diverse food crops namely maize and beans, and unconventional starch sources such as banana (Musa paradisiaca L.), mango (Mangifera indica L.), amaranth (Amaranthus hypochondriacus), and barley (Hordeum vulgare), among others. The starch after cooking, the storage of starchy products and the potential of starch isolated from unconventional sources to produce resistant starch-rich products using different treatments are emphasized.

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Isolation and Partial Characterization of Mexican Oxalis tuberosa Starch

Cited by 42 publications

References 27 publications

Thermal and rheological properties of nixtamalized maize starch

Thermal and rheological properties of nixtamalized maize starch

Enzymatic modification of cassava starch (Corpoica M-Tai) around the pasting temperature

Starches of Some Food Crops, Changes During Processing and Their Nutraceutical Potential

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