Quality Characteristics and Moisture Mobility of Giant Salamander (<i>Andrias davidianus</i>) Jerky during Roasting Process

Jin, Wengang; Chen, Xiaohua; Geng, Jingzhang; Jin, Jing; Pei, Jinjin; Gao, Ruichang; Chen, Dejing

doi:https://doi.org/10.1155/2021/9970797

Journal of Food Quality

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Abstract Introduction Materials and Methods Results and Discussion Conclusion Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2021 | Article ID 9970797 | https://doi.org/10.1155/2021/9970797

Quality Characteristics and Moisture Mobility of Giant Salamander (Andrias davidianus) Jerky during Roasting Process

Wengang Jin,¹Xiaohua Chen,¹Jingzhang Geng,¹Jing Jin,¹Jinjin Pei,¹Ruichang Gao,^1,2and Dejing Chen¹

Academic Editor: Luis Patarata

Received10 Mar 2021

Accepted23 Jun 2021

Published01 Jul 2021

Abstract

Quality attributes and water mobility of giant salamander jerkies (GSJs) during roasting process (160°C, for 0, 20, 40, 60, and 80 min) were investigated. The results showed that values and shear force increased of GSJs roasting from 20 to 80 min, while , yield, and moisture content decreased significantly (). Sensory assessment showed that GSJs at a roasting time of 40–60 min had higher scores. GSJs contained great amount of healthy unsaturated fatty acids (including DHA and EPA), and the total amino acids and essential amino acids were among 59.33–71.77 g·100 g⁻¹ and 25.94–31.40 g·100 g⁻¹, respectively. The mobility of the immobilized moisture and free moisture were shrunk dramatically during roasting. The proton density weighted images also exhibited the moisture shrinkage during roasting. In addition, T₂₂ and T₂₃ were positively correlated with MRI signal, moisture content, and yield of GSJs, but negatively correlated with shear force and overall acceptability, respectively. Thus, in view of various quality attributes and sensory evaluation, a roasting time of 40–60 min was favored for nutritive GSJs production. LF-NMR and MRI might be employed to profile the quality characteristics during roasting as a rapid and nondestructive analytical tool.

1. Introduction

Giant salamander (Andrias davidianus) lives as the biggest amphibian on planet Earth, mainly populated in central and south China [1, 2]. Dwelling on planet Earth for approximately 350 million oldness, giant salamander had once been overexploited, due to commercial interests for foods, nutraceutical, and medicines, and it was by that hold as an extinct wildlife [2, 3], Currently, man-made reproducing and farming of Andrias davidianus have been industrialized in some provinces of China, such as Shaanxi, Hunan, Henan, and Guizhou [3, 4]. In view of its increasing quantity and decreasing price, much effort upon utilization approaches of cultured Andrias davidianus has been made to increase its added value [4]. To date, bioactive peptides [5–7], cutting meat [8, 9], collagen or gelatin [4, 10–12], chondroitin sulfate [13], edible oil [14], and cooked dishes [15] from giant salamander have been previously reported.

Jerky is an intermediate-moisture convenience food fascinated by consumers worldwide [16]. Generally, sliced muscles of beef, pork, chicken, and fish have been roasted to manufacture jerky products. Silva et al. found that chicken jerky suffered acute oxidation and quality deterioration after storage at retail conditions [17]. Han et al. pointed out that curing methods would impact the quality characteristics of jerky [18]. Several reports also found that processing conditions (cooking methods, roasting temperature, and time) would affect processing yield, color, shear force, water activity, and volatile compounds of jerky [19–22]. Therefore, the physicochemical and quality characteristics of jerky are very critical for the final product quality control.

Roasting, a common practice during jerky processing, involves both mass and heat transfer. Roasting can endow jerky with favorable traits and the moisture dehydration of raw meat, depending on heat intensity and processing time [22]. Moisture migration and distribution are inevitable during jerky roasting, and their characterizations might be helpful for product quality control [19, 23]. These years, low-field nuclear magnetic resonance (LF-NMR) has been broadly used as a nondestructive technique for depiction of moisture distribution and migration in agricultural products processing, because of its agility, swiftness, nondestructiveness, and cheapness [24, 25]. Principle of LF-NMR chiefly laid on the determination of resonant radio frequency assimilation when imposed to a foreign fixed magnetic device. Spin-spin transverse relaxometry detection (T₂), coupled with T₂ opposite contour spectrum, is deemed to produce signal of moisture level, environmental attributes of moisture, and communication of moisture with the nearby macromolecules [24]. Magnetic resonance imaging (MRI), the second form of NMR relaxometry, can offer visualized signal of water migration and distribution [25, 26]. Up to now, LF-NMR and MRI techniques enjoy wide application in food quality characterization, especially quantification the variations of moisture allotment and movability involved in food processing and storage [27, 28].

In the field of processing of jerky-like products, Li et al. [29] studied the variations in moisture movability of chicken jerky after dehydrating with LF-NMR technique and found that acute interactions were spotted between moisture content, shear force, and LF-NMR signals. Song et al. [25] reported that the moisture changes in dehydrated abalone could be characterized by LF-NMR signals, and a simulation equation of water level was made employing the acute correlation between LF-NMR signals and water levels. Cheng et al. [24] pointed that LF-NMR and MRI facilities might be adopted to notice the water movability and allotment of Pacific oyster after dehydrating. These studies showed that LF-NMR and MRI facilities were potential tools for fast assay of the moisture dynamics and distribution of semidried products, and they might be used for quality control when combined with physicochemical and nutritional attributes [26, 27].

In the context of exploitation and utilization of farmed giant salamander, the use of its meat for jerky production could increase its added value and commercial product variety, yet little literature about the preparation and quality characteristics of giant salamander jerky could be found. The aim of present study was to explore the influence of roasting process upon the quality characteristics and water mobility of giant salamander jerkies (GSJs) during roasting. Besides, the nutritional and microstructure of the resulting jerky were also reported.

2. Materials and Methods

2.1. Raw Materials and Ingredients

Five frozen giant salamanders (approximately 2.57 ± 0.41 kg) were purchased from Hanzhong Dragon Head Mountain Aquatic Co., Ltd. (Shaanxi, China) and kept in a commercial refrigerator (CF50 Dometic Group, Shenzhen, China) at −20°C before use. Several condiments such as cooking wine, prickly ash, ginger, onion, sugar, salt, and pepper were bought from a local supermarket (Hanzhong, China), sealed with plastic bags, and stored at 4°C for 5 days in a chromatography cabinet (GSP, Yiran Refrigerator Co., Ltd., Beijing, China).

2.2. Preparation of Giant Salamander Jerky

Frozen giant salamander carcasses were first thawed with running water at room temperature (22°C), washed clean, sliced into around 250 bar-like samples (approximately 3 cm × 2 cm × 1 cm), and weighed. These samples were cured and deodored in a complex seasoning containing cooking wine, prickly ash, ginger, onion, sugar, salt, and pepper for 90 min. After draining juice, 250 sliced samples were roasted in a multifunction oven (Rational SCC61, Germany) for preparation of control (40 jerky samples) and roasted jerky (200 samples, 50 for each roasting time). The roasting temperature was set at 160°C for various time intervals (20, 40, 60, and 80 min), and samples without roasting were used as control (0 min). Then, jerky samples of each roasting time (0, 20, 40, 60, and 80 min) were cooled to room temperature, put into polyethylene bags, and sealed in a vacuum packing machine (DZ-600/2S, Tianjin Food Machinery Co., Ltd., Zhucheng, China), respectively. All jerky samples were subjected to the following measurement.

2.3. Yield Determination

The jerky yield was calculated according to a modified method of Kim et al. [30]. Briefly, 5 jerky samples at each roasting time (20, 40, 60, and 80 min) were weighed, respectively, before and after roasting, and yield was expressed by the percentage of weight before and after each roasting time, using the following formula:

2.4. Measurement of Shear Force

The shear force of 10 prepared jerky specimens after each roasting time (0, 20, 40, 60, and 80 min) was measured through a TA-XT2i Texture Analyzer (Stable Micro Systems, Godalming, UK), according to an adjusted method of Yang et al. [31]. The jerky samples (cooled to room temperature) were dressed evenly before test. Apparatus conditions were adjusted as follows: Warner–Bratzler blade probe, pretest velocity: 2.0 mm/s, test velocity: 2.0 mm/s; posttest velocity: 8.0 mm/s; shear depth: 15 mm; and induction load: 5 g.

2.5. Chromatism Assay

The surface chromatism of jerky samples was evaluated by a premium colorimeter (NH Technical Co., Ltd., Shenzhen, China). The CIELAB color system was used to obtain the parameters of (lightness), (redness), and (yellowness), prior to standardization with a white calibration plate. Three samples for each roasting time were prepared for color analysis, and six surface positions of single specimen were selected to get color parameters as mean.

2.6. Assay of Moisture Content

Jerky samples (5 for control and 5 for each roasting time) were assayed in a blast air oven (Hebi Metallurgical Machinery Equipment Co., Ltd., Henan, China) at 105°C until constant weight, according to GB5009.3-2016 (National Food Safety Standard of China). The moisture level was calculated by the mass variation before and after dehydrating [25].

2.7. Fatty Acid Determination

Fatty acid analysis of jerky samples (3 for control and 3 for each roasting time) was performed by gas chromatography (Agilent Technologies 7890A, USA) equipped with flame ionization detection and capillary DB-Wax column (30 m × 0.25 mm id × 0.25 μm film thickness, Agilent Technologies, USA). Each fatty acid in the chromatogram was detected by contrasting the retention times with standard mixes (FAME Mix Supelco, Bellefonte, PA, USA). The content of each fatty acid was calculated using the peak area normalization method by gas chromatography software. The detailed procedure and instrumental parameters were reported previously [32].

2.8. Amino Acid Analysis

Hydrolyzed using a 6 mol·L⁻¹ HCI solution at 105°C for 24 h, amino acid compositions of jerky specimens (3 for control and 3 for each roasting time) were performed by HPLC (Thermo Fisher Scientific Co., USA), installed with an amino acid kit reported previously [4]. Alkaline hydrolysis was also performed for the determination of tryptophan level.

2.9. Microstructure Analysis

The jerky specimens (3 for control and 3 for each roasting time) were dipped in 3% glutaraldehyde at 4°C for 12 h and then lyophilized in a freeze-drier (Sihuan Scientific Co., Ltd., Beijing, China). After this treatment, the microstructural photos of jerky samples were captured in a scanning electric microscopy (SEM) (Phenom Pure, Shanghai, China), at a magnification of 230x and 5 kV voltage.

2.10. Sensory Assessment

Sensory assessment of the jerky specimens was performed by the quantitative descriptive analysis (QDA) and the Hedonic test, according to a modified approach described previously [33, 34]. Ten panelists with no rhinitis and smoking (5 males and 5 females, age of 22–32) were recruited from Meat Laboratory of Department of Food Science, Shaanxi University of Technology. Three training sessions were held to familiarize the panelists with the aim, detailed experimental steps, and requirements of sensory assessment before serving jerky samples at various roasting times. Cold jerky samples (5 for control and 5 for each roasting time) were sliced before serving, respectively. The samples of different roasting times were finally served to panelists in a random order. Sensory assessment conditions included room temperature around 23–25°C and humidity of 50–54%, and filament lamp (36 W) was employed. Each assessor provided their scores for appearance, flavor, and texture through a 9-point descriptive scale (1.0–3.0, weak; 4.0–6.0, medium; and 7.0–9.0, strong). The value of 1.0 corresponded to the lowest score for each attribute and 9.0 to the highest. On the hedonic scale, 1.0–3.0 was deemed as not acceptable, 4.0-5.0 fairly acceptable, 6.0-7.0 good (acceptable), and 8.0-9.0 very good.

2.11. LF-NMR and MRI Trial

The T₂ transverse relaxation trials were carried out in a NMR analyzer (HT-MRSI20-40A; Huantong Instrumental Corporation, Shanghai, China). The resonance frequency and magnetic field intensity of the device was 23.2 MHz and 0.5 T. The jerkies (5 for control and 5 for each roasting time) were put into a hydrostatic glass column, and a 40 mm diameter radio frequency loop was employed to acquire Carr–Purcell–Meiboom–Gill sequence decline information, with 90° pulse time of 24 μs and 180° pulse time of 48 μs, respectively. The repetition time between two scans was 1.2 ms, and the other parameters included the number of echos = 2048, number of iterations = 10, number of points = 200, and signal-to-noise ratio = 300.

Magnetic resonance images (MRI) were also captured on the NMR instrument with the imaging software (Vs-Ultimate, Huantong Instrumental Corporation, Shanghai, China). Proton density weighted images were captured by the above NMR imaging procedure. The following scanning conditions were used: view field = 256 mm × 256 mm, resonant frequency = 23.2 MHz, pulse interval = 1, and repetition time = 20. The final images and the corresponding signal intensity after normalization was obtained by Image Pro software.

2.12. Statistical Approach

Obtained data were displayed as mean ± standard deviation (n ≥ 3). Figures are plotted through Origin Pro 2018 (OriginLab Co., USA). The acute variation was performed through ANOVA Tukey’s tests by IBM Statistics SPSS 24 (SPSS Inc., USA).

3. Results and Discussion

3.1. Quality Attributes as Influenced by Roasting Time

The present study monitored several quality parameters (processing yield, shear force, moisture content, and color values) of giant salamander jerkys (GSJs) during roasting process (Figure 1). The processing yield changes of GSJs prepared at different roasting times are shown in Figure 1(a). The yield of GSJs significantly decreased with roasting time (). In contrast with raw (0 min), processing yield of giant salamander meat roasted for 20 min decreased to 74.36%. The yield continued diminishing with the increase of roasting time. A lower yield of 30.05% was found when roasted for 80 min in the present study. This yield trend was mainly caused by water evaporation during roasting, as cooking loss of meat products occurred commonly during food processing [16, 21]. Low processing yield could enhance product quality and storage stability, but it sometimes harmed the economic interest of manufactures. Similar results of beef jerky fried at different temperatures were also reported by Liu et al. [23].

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(b)

(c)

(d)

Figure 1(b) profiles the moisture proportion of GSJs with different roasting times. The initial moisture content of giant salamander meat sample before roasting (0 min) was 72.81 ± 1.35%, lower than that of Veal (75.26%) and Hashi (76.44%), but higher than that of Noeimi (64.12%) and Najdi (71.82%) [35]. With the increase of roasting time (20–80 min), the moisture content of GSJs decreased significantly from 54.33 ± 1.58% to 26.44 ± 0.65% () (Figure 1(b)), owing to water evaporation caused by heat transfer during roasting [36, 37].

Shear force is a common quality indicator of meat products, which can reflect the texture of meat. Figure 1(c) shows the shear force of GSJs after various roasting times. No sharp variation for shear force of GSJs was found when roasted for 0 and 20 min (), although a slight increase was observed at 20 min. The shear force value increased sharply when roasted above 40 min (). Through roasting, the water proportion of giant salamander jerky decreased with increasing roasting time, and myofibrillar proteins suffered severe denaturation and cross-linking, leading to crust hardness of dried meat [36–38].

Surface color of meat jerky products is a critical attribute for consumers’ food choice. The instrumental color parameters of GSJs with different roasting times are shown in Figure 1(d). The value of GSJs after roasting 20 min were greater than initial raw jerky (0 min) (), whereas and parameters slightly fluctuated (). Once roasting, raw meat protein denatured gradually because of heat stress, leading to the increase of value. With the extension of roasting time from 40 to 80 min, the value (lightness) decreased significantly, while (redness) and (yellowness) values increased gradually (). This is because moisture escaped from jerky samples during roasting; some browning compounds may be produced through Maillard reaction between protein, amino acid, and carbonyl of giant salamander’s muscle [39]. A similar color result of fish fillets grilled with various time intervals was also reported previously [19].

3.2. Sensory Scores, Fatty Acids, and Amino Acids of GSJs

Several researchers found that flavor and tenderness were the most important among various sensory attributes of jerky products. The hedonic test obtained scores, including appearance, flavor, texture, and whole acceptability of GSJs with different roasting times, are summarized in Table 1. It demonstrated that sensory outlook, flavor, and overall acceptability of GSJs increased from 20 to 60 min, and then these quality profiles decreased to certain degree (80 min). The texture score increased when roasted up to 80 min, because of moisture reduction, protein denaturation, and cross-linking, leading to the formation of crust rigidity of jerky products [36, 38]. The present study recommended that 40–60 min of roasting was the optimum condition for production of GSJs, after weighing various sensory profiles.

Fatty acids can not only improve meat taste, but also offer calories and health-promoting polyunsaturated fatty acids for human body [40, 41]. Table 2 illustrates the overall fatty acid compositions of GSJs with different roasting times. As shown, both saturated fatty acids (SFAs) and unsaturated fatty acids (UFAs) of GSJs enhanced obviously after roasting (); especially, a jump was observed when GSJs roasted for 20 min. Then, SFAs and UFAs were diminished significantly when roasting from 20 to 80 min. Compared to raw (0 min), all GSJs after roasting showed higher content of SFAs and UFAs. SFAs in meat products would increase when subjected to a dry-heat cooking process, primarily because of oxidation of unsaturated bonds from fatty acids. C16:0 was found to be the relative more abundant saturated fatty acids (249.65–642.45 mg·100 g⁻¹) in GSJs, which was similar with previous reports about cooked orange-spotted grouper (Epinephelus coioides) [42], wild sea bream (Sparus aurata) [41], and roasted sardines (Sardinella brasiliensis) [43].

Table 2 also shows that GSJs contained more unsaturated fatty acids (2189.45–3509.01 mg·100 g⁻¹), including MUFAs (1156.45–1941.34 mg·100 g⁻¹) and PUFAs (1033.007–1567.67 mg·100 g⁻¹). Meanwhile, the contents of C20:5n3 (EPA) and C22:6n3 (DHA) in GSJs were relatively higher than other polyunsaturated fatty acids, which implied its potential health benefits correlated with many chronic cardiovascular symptoms [44]. The present study found that compared with raw (0 min), both MUFAs and PUFAs (including DHA and EPA) increased significantly () when roasting for 20 min and then decreased significantly as roasting from 20 to 80 min. Several literatures demonstrated that MUFAs and PUFAs of meat and aquatic products would be promptly destroyed after thermal processing [42, 44, 45]. Although the content of MUFAs and PUFAs in GSJs decreased significantly with extension of roasting time, GSJs after roasting still showed higher unsaturated fatty acids (including DHA and EPA) than raw control (0 min), perhaps owing to giant salamander’s high unsaturated fatty acids content. The present fatty acid profile results were in agreement with previous reports, such as pork, lamb, sardines, and sea bream after dry-heat cooking process [41, 43–46]. Therefore, GSJs might be considered as a novel jerky product with great amount of healthy unsaturated fatty acids.

Table 3 shows the amino acid compositions of GSJs with different roasting times, as well as total essential amino acids (TEAAs) and total amino acids (TAAs). As shown, roasting process could fluctuate the amino acid profile of GSJs to certain extent, chiefly owing to protein and lipid oxidation during roasting [17, 19, 20]. The most abundant amino acids in GSJs were glutamic acid (9.35–11.3 g·100 g⁻¹), aspartic acid (5.99–7.29 g·100 g⁻¹), lysine (5.44–6.71 g·100 g⁻¹), leucine (4.94–6.00 g·100 g⁻¹), and alanine (4.04–4.94 g·100 g⁻¹). The total amino acids and essential amino acids were among 59.33–71.77 g·100 g⁻¹ and 25.94–31.40 g·100 g⁻¹, respectively, which was higher than claw meat (Eriocheir sinensis) [40]. Therefore, GSJs could also be considered as a nutritive jerky product with balanced amino acid compositions.

3.3. SEM Microstructure of GSJs during Roasting Process

To further understand the muscular tissue during roasting, the SEM photo of GSJs with different roasting times was captured and is shown in Figure 2. As can be seen, the muscle fibers of GSJs experience certain aggregation when roasted from 0 to 20 min, and then suffered to some extent depolymerization and fracture when roasted from 40 to 80 min, which could cause corresponding texture and sensory quality changes of jerky during roasting. This phenomenon was mainly owing to initial protein denaturation, shrinkage, and water evaporation caused by heat transfer during roasting [36–39].

(a)

(b)

(c)

(d)

(e)

3.4. LF-NMR and MRI Signals as Affected by Roasting Time

Figure 3 exhibits the profile of T₂ relaxation spectrum acquired by polyexponential simulating of constant allotted CPMG spectra for GSJs with different roasting time. Before roasting (0 min), the curve signal showed two major groups with the T₂ time around 65.06 and 613.59 ms. But after roasting for 20 min, the third group with the T₂ time below 10 ms appeared in grilled jerky products. The first peak T₂₁ with the minimum time below 10 ms, generally, is considered as bound moisture, which is closely combined with nearby substances. The second peak T₂₂ around 10–100 ms is thought to be immobilized moisture captured in meat lattice. The third peak T₂₃ with the maximum time around 100–1000 ms is deemed to bulk moisture [24, 25].

Figure 3 shows that the T₂ of bound, immobilized, and bulk moisture of GSJs all diminished after roasting from 20 to 80 min, which implied the reduction of water mobility. The quantitative data of T₂₁, T₂₂, and T₂₃ and corresponding peak areas A₂₁, A₂₂, and A₂₃ of GSJs among various roasting intervals are shown in Table 4. The T₂₁ diminished from 4.08 ms for GSJs roasted 20 min, to 2.87 ms for 40 min, 1.73 ms for 60 min, and 1.04 ms for 80 min. With the roasting time extending (20–80 min), T₂₂ decreased from 65.06 ms to 14.17 ms (), and T₂₃ decreased from 613.59 ms to 86.97 ms (), respectively.

As the peak proportion of T₂ components generally is directly correlated with moisture level in food products, the present data demonstrated that the proportion of bound moisture A₂₁ enhanced from 11.95 to 72.06 (), the proportion of immobilized moisture A₂₂ decreased from 3933.56 to 1622.75, and the proportion of bulk moisture A₂₃ enhanced from 109.31 to 598.19 () and then decreased from 598.19 to 100.80. It can be seen that these NMR signals illustrated that the movabilities of bound, immobilized, and bulk moisture for GSJs were shrunk to some extent, mainly owing to the moisture evaporation loss during roasting process [25, 27]. A similar result of Pacific oyster after hot-air dehydrating at various time intervals was also reported previously [24].

Figure 4(a) shows the moisture allotment of GSJs by MRI through the proton density weighted photos, obtained during the roasting process for each sample. The red region denotes high proton accumulation, and the blue region denotes low proton accumulation. With the prolongation of roasting time, a steady diminishment was noticed by the proton signals of brighter proportion, implying the drop of longer T₂ signal of moisture after roasting [24, 27]. In addition, the shrinkage of proton signal from outer surface to inward district can be found clearly. Meantime, the red district almost disappeared for GSJs after 80 min roasting with 26.44% water proportion, implying low proton accumulation. This phenomenon was because of the water evaporation caused by heat transfer during roasting [16, 19]. Figure 4(b) depicts the quantitative proton accumulation of Figure 4(a), which shrunk obviously during roasting. These results were in agreement with previous reports about dried abalone at different drying times [25].

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(b)

3.5. Correlation Analysis of Various Parameters

Correlation analysis between the quality characteristics and NMR relaxation parameters was performed by bivariate analysis Pearson’s correlation coefficient, and the results showed that the relaxation time T₂₂, T₂₃ and quality attributes displayed excellent correlations as shown in Table 5.

The corresponding correlation coefficients of T₂₂ and T₂₃ were positively correlated with MRI signal, moisture content, and yield of GSJs, but negatively correlated with shear force and overall acceptability, respectively (Table 5). This result demonstrates that the immobilized water and free water are the main form of the moisture and determines the changes of quality characteristic of GSJs during the roasting process [19, 24]. Thus, the LF-NMR data could be applied to predict the moisture content and quality characteristics of GSJs during the roasting process as a fast and nondestructive method [32, 47].

4. Conclusion

In summary, the values and shear force of giant salamander jerkies (GSJs) increased when roasting from 20 to 80 min, while , yield, and moisture content decreased significantly (). Sensory assessment showed the whole acceptability of GSJs at a roasting time of 40–60 min had higher scores. GSJs contained great amount of healthy unsaturated fatty acids (including DHA and EPA), and the total amino acids and essential amino acids were among 59.33–71.77 g·100 g⁻¹ and 25.94–31.40 g·100 g⁻¹, respectively. The mobility of the immobilized and bulk moisture was shrunk dramatically after roasting. The proton density weighted photos also depicted the moisture diminishment during roasting. In addition, T₂₂ and T₂₃ were positively correlated with MRI signal, moisture content, and yield of GSJs, but negatively correlated with shear force and overall acceptability, respectively. Thus, in view of various quality attributes and sensory evaluation, a roasting time of 40–60 min was favored for nutritive GSJs production, and LF-NMR and MRI might be employed to profile the quality characteristics during roasting as a rapid and nondestructive analytical tool.

Data Availability

All data generated or analysed during this study are included in this article.

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this study.

Wengang Jin and Xiaohua Chen contributed equally to this work.

Authors’ Contributions

Wengang Jin and Xiaohua Chen conducted investigation, wrote the original draft, and performed plot analysis. Jingzhang Geng performed partial analysis and visualization. Jing Jin, Jinjin Pei, and Dejing Chen collected resources and tested amino acid and fatty acid content. Ruichang Gao reviewed and edited the manuscript, supervised the work, and acquired funding.

Acknowledgments

This study was mainly funded by Collaborative Innovation Center Project for Qin-Ba Mountain Bio-Resources Utilization and Development (no. QBXT-18-04) and China Scholarship Council (no. 202008610071), and partial fund from Shaanxi “Sanqin Scholar” Innovation Team was greatly appreciated.

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Copyright © 2021 Wengang Jin et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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