Impact of short‐term thermal treatment on stingless bee honey (<i>Meliponinae)</i>: Quality, phenolic compounds and antioxidant capacity

Braghini, Francieli; Biluca, Fabíola Carina; Gonzaga, Luciano Valdomiro; Kracik, Aline S.; Vieira, Cleide Rosana Werneck; Vitali, Luciano; Micke, Gustavo Amadeu; Costa, Ana Carolina Oliveira; Fett, Roseane

doi:10.1111/jfpp.13954

Cited by 26 publications

(26 citation statements)

References 33 publications

(55 reference statements)

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“…(2018) also did not detect the formation of 5‐HMF after thermal processing of stingless bee honey, confirming this hypothesis. These studies show that 5‐HMF was not detected in stingless bee honey when applied 75–95°C for 20–60 s (Biluca et al., 2014); in Melipona bicolor honey at 90–95°C for 15–60 s (Braghini et al., 2019); and in Melipona fasciculata honey at 65°C for 30 min (Ribeiro et al., 2018), confirming this hypothesis.…”

Section: Resultsmentioning

confidence: 62%

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Physicochemical parameters, bioactive compounds, and antibacterial potential of stingless bee honey

Biluca

Braghini

Ferreira

et al. 2020

J. Food Process. Preserv.

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Analysis of physicochemical parameters, phenolic compounds, total reducing capacity, free radical scavenging, and antimicrobial potential was performed in 14 samples of honey from six different species of stingless bees from Brazil. The results of the physicochemical properties showed high moisture (24.28%–38.20% wt/wt), free acidity above 50 meq/kg for most honey samples, reducing sugars ranging from 58.79% to 73.01% (wt/wt), 5‐hydroxymethylfurfural (5‐HMF) below the limit of quantification (0.074 mg/L), diastase activity from <3 to 70.91 Göthe units, and electrical conductivity values varying from 0.13 to 0.84 mS cm−1. In addition, 12 phenolic compounds were quantified, being taxifolin (

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Section: Resultsmentioning

confidence: 62%

“…Braghini et al. (2019) and Ribeiro et al. (2018) also did not detect the formation of 5‐HMF after thermal processing of stingless bee honey, confirming this hypothesis.…”

Section: Resultsmentioning

confidence: 76%

Physicochemical parameters, bioactive compounds, and antibacterial potential of stingless bee honey

Biluca

Braghini

Ferreira

et al. 2020

J. Food Process. Preserv.

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“…In order to provide a wider and more competitive market for stingless bee honey, the obstacle of short shelf life and product instability due to its high moisture content should be addressed. However, only a few studies have been carried out to uphold the problem (Braghini et al., 2019; Carvalho et al., 2009; Chong et al., 2017; Ramli et al., 2018). In brief, Chong et al.…”

Section: Introductionmentioning

confidence: 99%

“…Braghini et al. (2019) reported that a short‐term thermal treatment can be an alternative method to preserve stingless bee honey without removal of the moisture. It caused no significant effect on the physicochemical characteristics of stingless bee honey meanwhile successfully improves microbial quality and some biological properties.…”

Section: Introductionmentioning

confidence: 99%

Effect of drying on physicochemical and functional properties of stingless bee honey

Chen

Chuah

Chye

2021

J. Food Process. Preserv.

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The study aimed to evaluate the effect of drying on the functional quality of stingless bee (Heterotrigona itama) honey. The honey was subjected to vacuum drying (40–60°C), vacuum evaporation (40–60°C), and freeze drying, respectively, to achieve a standardized moisture content. The dehydrated honey seemed to have a significant (p < .05) darker color (lower L* and higher b* values) as compared to the raw honey. Results suggested that the dryness of the dehydrated honey has significantly affected its antioxidant capacity except oxygen radical absorbance capacity (ORAC) assay. It seems vacuum drying at 60°C for 2.2 hr produced honey with higher total phenolic (300.24 ± 6.81 mg GAE/kg) and flavonoid contents (273.83 ± 2.52 mg QE/kg), which were also characterized by the highest 2,2‐azinobis‐(3‐ethylbenzothiazoline‐6‐sulphonate) (ABTS) (371.34 ± 2.57 µmol TE/100 g) and ferric reducing antioxidant power (FRAP) (344.20 ± 6.81 µmol Fe2+/100 g). Rosmarinic acid and quercetin are the most dominant phenolic compounds found in the dehydrated honey. In conclusion, vacuum drying could be an efficient way to improve honey physicochemical and functional stability. Practical applications Stingless bee honey production is a new emerging industry in tropical and subtropical countries. The keeping quality of stingless bee honey is limited due to its nature of high moisture content. Thus, removal of excessive moisture from the honey is necessary to maintain the product quality and stability particularly during handling and storage. The application of low‐pressure dehydration processes can aid the evaporation process of water from stingless bee honey. The findings of the present work provide a better insight toward the effect of low‐pressure dehydration on the physicochemical quality and functional properties of stingless bee honey in addition to extend its shelf life.

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“…With a global production of 183 million tons during 2015 and 179 million tons in 2016 [3] and a growing demand from the consumer market, it is interesting to ensure the conservation of honey for as long as possible. In order to achieve this objective, thermal treatment is used more frequently every day, since this method is easy to apply and ensures the reduction or elimination of micro-organisms [4] that can significantly affect the shelf life and therefore its quality for consumption [5].…”

Section: Introductionmentioning

confidence: 99%

Optical Determination of the Effects by Thermal Treatment (TT) in Honey of <i>Apis mellifera</i> Bees

Quevedo¹,

Pensado²,

Romero³

et al. 2020

JACEN

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Spectroscopy in the UV-Vis and NIR ranges of light provides great convenience for the characterization and evaluation of the characteristics and optical modifications that occur during life, the processes for the preparation of some food in order to modify their characteristics or eliminate Microorganisms that can affect their quality and shelf life, work is carried out at elevated temperatures, even above 100˚C. The study has made it possible to identify changes in the Absorbance, Transmittance and Optical Intensity of Apis mellifera honey from four different botanical sources and States of the Mexican Republic: Citrus (Citrus) from the state of Veracruz, Mangle (Rizophora mangle) of the Pacific zone of the state of Sinaloa, Polyfloralis of the state of Morelos and Polyfloralis of the state of Tabasco.

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Impact of short‐term thermal treatment on stingless bee honey (Meliponinae): Quality, phenolic compounds and antioxidant capacity

Cited by 26 publications

References 33 publications

Physicochemical parameters, bioactive compounds, and antibacterial potential of stingless bee honey

Physicochemical parameters, bioactive compounds, and antibacterial potential of stingless bee honey

Effect of drying on physicochemical and functional properties of stingless bee honey

Optical Determination of the Effects by Thermal Treatment (TT) in Honey of <i>Apis mellifera</i> Bees

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Impact of short‐term thermal treatment on stingless bee honey (Meliponinae): Quality, phenolic compounds and antioxidant capacity

Cited by 26 publications

References 33 publications

Physicochemical parameters, bioactive compounds, and antibacterial potential of stingless bee honey

Physicochemical parameters, bioactive compounds, and antibacterial potential of stingless bee honey

Effect of drying on physicochemical and functional properties of stingless bee honey

Optical Determination of the Effects by Thermal Treatment (TT) in Honey of &lt;i&gt;Apis mellifera&lt;/i&gt; Bees

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Optical Determination of the Effects by Thermal Treatment (TT) in Honey of <i>Apis mellifera</i> Bees