Nathália Torres Corrêa Magri scite author profile

Insects have evolved multiple mechanisms to adapt to variations in environmental temperatures, including postural control of solar input, variations in diurnal activity, external morphological structures and selecting/generating microhabitats. Foam produced by Mahanarva fimbriolata nymphs (also known as root spittlebugs) was found to aid in creating a constant thermal microhabitat despite environmental temperature fluctuations. The temperature within the foam was found to be similar to that of soil during the day and remained constant despite fluctuating external temperatures. In chemically analysing the composition of the foam, palmitic and stearic acids, carbohydrates and proteins were detected. These substances have previously been shown to act as a surfactant to stabilize and modulate foams. Since the immature ancestor of the spittlebug developed below ground, it is speculated that the foam may function as an ‘extension’ of the soil and, thus, may have enabled the spittlebug to emerge from the soil and adopt an epigean lifestyle.

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Sugarcane Juice Clarification by Hydrogen Peroxide: Predictions with Artificial Neural Networks

Sartori

Ribeiro

Teixeira

et al. 2017

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Hydrogen peroxide has been studied as an alternative for sulfur in the white sugar industry. Sulfur has been associated to allergic diseases, mainly asthma. In this study, artificial neural network (ANN) models are proposed to predict the effects of different variables (peroxidation time, temperature, pH, H2O2 dosage, and initial °Brix) on sugarcane juice color removal and sucrose content. Experimental results and the ANN models revealed that temperature showed the greatest influence on the decrease of juice color; nevertheless, the effect of temperature depended on pH: at pH<;5.0 a decrease in juice absorbance was observed at temperatures close to 38 °C, whereas in the pH range of 5.0–6.3, absorbance decreased only at about 50–62 °C, regardless of the amount of hydrogen peroxide used. On the other hand, the remaining sucrose content after peroxidation was influenced by the initial °Brix and by pH.

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Clarificação de caldo de cana-de-açúcar por peróxido de hidrogênio: efeito da presença de dextrana

Sartori

Magri

Aguiar

2015

Braz. J. Food Technol.

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Resumo A qualidade do açúcar cristal está diretamente associada à qualidade da cana-de-açúcar (Saccharum sp.) entregue nas usinas e à eficiência do processo industrial. A dextrana é considerada um parâmetro de qualidade de matéria-prima, uma vez que sua presença indica que a cana-de-açúcar sofreu deterioração entre as etapas de corte e seu processamento. Durante o processamento do caldo, a dextrana pode interferir na eficiência do processo. Na etapa de clarificação, a sulfitação tem como principal objetivo promover a redução de cor ICUMSA do caldo de cana-de-açúcar. A cor ICUMSA é o parâmetro mais importante para a classificação comercial do açúcar no Brasil e quanto mais baixo o seu valor, mais claro é o açúcar. O peróxido de hidrogênio (H2O2) tem sido estudado na clarificação do caldo de cana-de-açúcar como possível agente clarificante em substituição ao sulfito, que apresenta contra-indicações à saúde respiratória humana. Teve-se como objetivo determinar o impacto da presença de dextrana na eficiência da redução de cor ICUMSA do caldo de cana-de-açúcar por peroxidação. Durante a peroxidação, a temperatura e o pH influenciaram significativamente na redução da cor ICUMSA do caldo, sendo que o aumento da temperatura, aumento da dose de peróxido de hidrogênio e diminuição do pH levaram à diminuição da cor ICUMSA. Os valores de dextrana utilizados (até 1.000 ppm) não mostraram influência significativa na redução da cor do caldo de cana-de-açúcar, mas apresentaram interações significativas com os demais parâmetros.

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Redução de cor ICUMSA em soluções concentradas de açúcar bruto por processo oxidativo com peróxido de hidrogênio

Mandro

Magri

Sartori

et al. 2017

Braz. J. Food Technol.

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Resumo A clarificação/purificação do açúcar refinado a partir de açúcares brutos, como Very High Polarization (VHP), é realizada atualmente pelo uso de resinas de troca-iônica ou carvão ativado. No entanto, são metodologias de alto custo, que necessitam de constante regeneração/recuperação e apresentam perda de capacidade em função do tempo de processamento. Neste sentido, estudos sobre tecnologias alternativas ao uso de resinas de troca-iônica e carvão ativado vêm sendo cada vez mais relacionados, para aumentar a economia do setor. O peróxido de hidrogênio em solução comercial (35%, v/v) pode também ser entendido como agente promotor de redução de cor ICUMSA, na cadeia produtiva do açúcar refinado. Com isso, foram realizados tratamentos a fim de testar a eficiência do agente oxidante na clarificação de açúcar bruto do tipo VHP. Os tratamentos foram avaliados frente a diferentes doses de peróxido de hidrogênio, pH e temperaturas, durante um tempo reacional de uma hora. Todas as amostras tratadas apresentaram redução de cor ICUMSA, sendo que o maior decréscimo esteve na faixa de 67 a 70%. O aumento da dose de agente oxidante foi proporcional ao aumento de precipitados no meio, em que o tratamento com maior concentração de peróxido de hidrogênio apresentou índice de turbidez de 142 NTU em relação ao valor da amostra bruta (17 NTU), sendo o ensaio com maior turbidez. A degradação de sacarose ocorreu de forma mais pronunciada nos tratamentos com valores de pH abaixo de 5,0. Com isso, o peróxido de hidrogênio se mostrou uma alternativa viável para redução de cor ICUMSA e precipitação de não-açúcares e os tratamentos com melhor redução de cor também não foram críticos na degradação de sacarose.

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Color reduction of raw sugar syrup using hydrogen peroxide

Campiol

Magri

Sartori

et al. 2019

Braz. J. Food Technol.

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A commercial H2O2 solution (35%, v/v) was evaluated as a clarifying agent for raw, type VHP (very high polarization) sugar syrup, using an experimental design applying artificial neural networks (ANN). Fifteen experimental runs were carried out and the samples were taken at the following time intervals: 0, 5, 10, 15, 20, 25, 30, 40, 50, 60, 75 and 90 min. The treatments were carried out using an experimental design consisting of three variables: H2O2 (X1: 0; 202.4; 500; 797.6 and 1.000 mg L-1); pH (X2: 3.32, 5, 7.5, 10 and 11.68) and temperature (X3: 16.4, 30, 50, 70 and 83.6°C). The theoretical and measured values fitted the analysis by artificial neural networks (ANN) well. A reduction in colour (ICUMSA method) was observed between 60 and 75 min, except for treatments # 11 (pH= 11.68; 50°C and 500 mgH2O2 L-1), # 13 (pH=7.5; 83.6°C and 500 mgH2O2 L-1) and #15 (pH= 7.5; 50°C and 1.000 mgH2O2 L-1), which showed a colour reduction after 30 min. In the treatments at pH 3.32 or 11.68, temperature of 83.6°C and H2O2 dose of 1.000 mg L-1, an average sucrose degradation of 55% was observed. The best colour reduction result was obtained with treatment # 9 (pH 7.5, 50 °C and 500 mgH2O2 L-1), although sucrose degradation of 26% was observed.

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Precipitation of nonsugars as a model of color reduction in sugarcane juice ( Saccharum spp.) submitted to the hydrogen peroxide clarification of the crystal sugar process

Magri

Sartori

Jara

et al. 2019

J Food Process Preserv

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Proteins, waxes, lipids, minerals, colloids, and pigments are known as nonsugars in sugarcanes and their precipitation has been associated with ICUMSA color reduction. This work aimed to evaluate the effect of three hydrogen peroxide doses (1,000; 5,000; and 10,000 mg/L), after 1 hr, on the ICUMSA color, turbidity, and total soluble solids (Brix) and by gas chromatography‐mass spectrometry the composition of the chemical compounds presents in precipitates formed by the action of hydrogen peroxide and in the sugarcane wax was identified. Reductions occurred in ICUMSA color for the three doses (39.7%, 48.3%, and 60.7%, respectively) and in the Brix (63.9%, 65.2%, and 67.1%, respectively). For turbidity, the dosage of 1,000 mg/L showed an increase (3.7%), while the others reduced (7.3% and 13.3%, respectively). By gas chromatography‐mass spectrometry, 32 compounds were identified, 10 of them were present in all the samples and the major class components were hydrocarbons and fatty acids. Practical applications In this work, we studied the potential application of hydrogen peroxide as an alternative of the sulfitation process, which it has been associated with health disturbs.

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Pretreatment of sugarcane top leaves by ozonation as a promotion of susceptibility to hidrolysis

Ogando¹,

Sartori²,

Magri³

et al. 2016

J. Bioen. Food Sci.

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