Abstract
Individual sugars were analyzed by high performance liquid chromatography (HPLC) in samples of apple juices obtained from the fruits of ‘Jonathan’, ‘Starkrimson’ and ‘Golden Delicious’ cultivars. Samples were harvested from the inside and the periphery of the crown, at different periods during fruits growth, from 7 to 144 days after full bloom (DAFB). Values from 0.42 to 14.33%, 0.29 to 4.06% and 0 to 4.28% were determined for fructose, glucose and sucrose, respectively. The values of fructose and glucose have increased significantly (p<0.05), starting with the seventh DAFB, regardless of the studied cultivar, while sucrose increased slowly at the beginning and then faster starting 65 DAFB. Fourier transform mid-infrared (FT-MIR) analysis confirmed the differences between juice samples, the region 900-1500 cm-1 being the most specific to sugars signals. FT-MIR coupled to partial least squares (PLS) calibration models for predicting individual sugars of apple juices were developed. The optimal regions and pre-treatments of the spectra were 900-1500 cm-1 and Savitzky Golay first derivative (d1) for fructose, 900-1200 cm-1 and d2 for glucose and 900-1200 cm-1 and standard normal variate for sucrose. In cross-validation, the PLS calibration models showed very good performance for fructose (Rcval 2=0.95; standard error of cross-validation (SECV) =0.907) and acceptable for glucose (Rcval 2=0.85; SECV=0.424), while for sucrose showed only satisfactory performance (Rcval 2=0.75; SECV=0.561). For practical relevance, the FT-MIR predicted values were compared against the HPLC determined reference values in external validations tests. The best results were achieved for fructose (Rp 2=0.94; RPD=4.9), while glucose (Rp 2=0.84; RPD=2.61) and sucrose (Rp 2=0.7; RPD=2.08) models reached satisfactory values.
Highlights
The apple is considered one of the most agreed fruit for both children and adults
high performance liquid chromatography (HPLC) analysis of apple juice sugars obtained from fruits harvested during development Table 1 shows the carbohydrate concentration for each cultivar, as a function of position and harvesting time
A similar increase in fructose and sucrose content was reported in previous studies for other apple cultivars, which concluded that the increase of sucrose occurs at the time of starch degradation (Berüter and Feusi 1997; Hecke et al, 2006; Petkovsek et al, 2007; Teo et al, 2006; Zhang et al, 2010)
Summary
The apple is considered one of the most agreed fruit for both children and adults. It is an important part of the human diet being a rich source of monosaccharides and biologically active compounds (Fuleki et al, 1994; Miller et al, 1997; Zhang et al, 2010; Zheng et al, 2012). Apples have a unique metabolism when it comes to sugar accumulation, because more than 80% of the total carbon flux is going through fructose, so fructose reaches higher levels. There are reports on the accumulation of apple carbohydrates and the changes caused by enzymes during growth, the accumulation of sugars remain unclear, being regulated at the level of gene expression (Chourey et al, 1985; Mingjun et al, 2012; Yamaki et al, 1992; Zhang et al, 2010)
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