Impacts of Inherent Components and Nitrogen Fertilizer on Eating and Cooking Quality of Rice: A Review

With the continuous improvement of living standards, the preferences of consumers are shifting to rice varieties with high eating and cooking quality (ECQ). Milled rice is mainly composed of starch, protein, and oil, which constitute the physicochemical basis of rice taste quality. This review summarizes the relationship between rice ECQ and its intrinsic ingredients, and also briefly introduces the effects of nitrogen fertilizer management on rice ECQ. Rice varieties with higher AC usually have more long branches of amylopectin, which leach less when cooking, leading to higher hardness, lower stickinesss, and less panelist preference. High PC impedes starch pasting, and it may be hard for heat and moisture to enter the rice interior, ultimately resulting in worse rice eating quality. Rice with higher lipid content had a brighter luster and better eating quality, and starch lipids in rice have a greater impact on rice eating quality than non-starch lipids. The application of nitrogen fertilizer can enhance rice yield, but it also decreases the ECQ of rice. CRNF has been widely used in cereal crops such as maize, wheat, and rice as a novel, environmentally friendly, and effective fertilizer, and could increase rice quality to a certain extent compared with conventional urea. This review shows a benefit to finding more reasonable nitrogen fertilizer management that can be used to regulate the physical and chemical indicators of rice grains in production and to improve the taste quality of rice without affecting yield.


Introduction
Rice is one of the principal staple foods that feeds more than 50% of the world's population [1]. The cultivation, consumption, and market of rice are primarily centered in Asia. It is reported that Asian farmers provided approximately 90% of the total rice production in the world, with China and India jointly contributing almost 51% [2]. According to the International Rice Information System, there are at least 5000 rice varieties that have been released, and many more if traditional rice varieties are included [3]. Rice is cultivated on over 164 Mha of lands in more than 100 countries every year [4]. It is expected that the global demand for rice will grow to 852 million tons by 2035 as the yield per unit area increases year by year [5].
Rice is the major source of nutrition, which can meet the daily need for calorie and protein of over two billion people in the world [6]. Reports showed that rice not only provides primary calories but also is a good source of micronutrients and macronutrients, Table 2. An overview of literature data on the sensory analysis of cooked rice.
Buenafe et al. [51] 5 classes of the benchmark varieties 5 males and females from India Appearance, elongation, tenderness on touching, cohesiveness, tenderness on chewing, taste, and aroma.
Classes A and E were deemed the most acceptable varieties with an overall acceptability of 3.9 and 4.0, respectively, out of 5.
Wandoaengmi6 was the best.
Rice edible quality had significant decrease after being stored two years.
The rice taste analyzer designed in Japan is an accurate, convenient, and efficient tool to evaluate rice cooking and eating characteristics [58]. It converted various physicochemical indexes of the rice into "taste" scores according to the correlations between the preference sensory scores and the near-infrared reflectance measurement values of the key components [58]. Nevertheless, some studies have pointed out that the accuracy of the system needs to be improved [59]. Yang et al. found that the eating quality of rice produced in Jiangsu province was comparable to that of northeastern rice based on the results evaluated by a trained panel. However, taste values obtained from the taste analyzer had different results that northeastern rice was superior to Jiangsu rice [24]. Therefore, the data obtained from the taste analyzer should be interpreted carefully when processing rice samples collected from contrasting growth conditions, and localizing the Japanese taste analyzer through correlating the chemical compositions including moisture, fatty acid, protein, and amylose with the taste scores of Chinese preferences is significant.

Relationship between Rice ECQ and Its Components
Rice ECQ mainly depends on its intrinsic ingredients [14]. Rice grains consist of about 80-85% starch, 4-10% protein, 1% lipid, and other components with few amounts, and the genetic variation range in biochemical constituents affects rice ECQ [60].

Starch
The proportion of starch in milled rice is about 90% [61]. As the largest component of endosperm of rice grain, starch contains two types of glucose polymers, including amylose and amylopectin. Amylose mostly consists of hundreds of glucose units with linear connections, whereas amylopectin is composed of thousands of glucose units and it is branched to a large degree via the α-1,6-glycosidic bond on the basis of amylose [62]. Rice components varies among varieties, resulting in variability in texture and pasting viscosity [63]. Sanjiva Rao and colleagues were the first to propose that there may be a relation between AC and rice quality [64]. Compared with low AC rice, cooked rice with high AC has slower digestibility and higher nutritional benefits, but worse eating quality [54]. After being cooked, high AC rice tends to have a dry and flaky texture, while rice with low AC would become soft and sticky [24]. Compared with low AC rice, rice with high AC requires less cooking time [65]. Typically, rice is divided into the following groups according to its AC: waxy (0-2%), extremely low (3-9%), low (10-19%), medium (20-25%), and high (>25%) [22]. Feng et al. indicated that too low or too high amylose content had negative effects on rice taste quality [66]. For rice that had more than 20% AC, its texture was hard after cooking, while rice with 15-20% AC had better quality after cooking [67]. Tao et al. also found that rice varieties (IR45427-2B-2-2B-1-1, Vandana, and Topaz) with high AC (≥25.9%) had a higher score for residual particles, roughness, dryness, and hardness, while rice with AC < 20% (Langi, YRF 216, Tachin i, and Hom Mali) is characterized by higher cohesiveness, stickiness, and tooth pack [54]. Medium AC samples (Remant, IR 65598-112-2, and Bengal) scored higher for preference, whereas samples IR45427-2B-2-2B-1-1, Vandana, and Topaz had low eating quality. It is reported that different AC and chain length can influence the formation and preservation of aroma compounds [68]. Kasemwong et al. announced that starch with high AC could complex more aroma molecules [69]. Wulff et al. also found that the association constant between the same aroma compounds and amylose was decided by amylose chain length [70]. An appropriate chain length is conducive to enhance the stability of compounds and the preservation of aroma.
The molecular structure of native rice starch influences the sensory properties of cooked rice [71], such as the remarkable positive correlation between AC of native rice starch and stiffness and the significant negative correlation between AC of native rice starch and stickiness [72]. Nevertheless, the mechanism behind the effects of starch on rice eating quality cannot be fully explained by AC alone. Amylopectin structure has an important impact on the physicochemical attributes of starch [71], which is the major cause for rice quality difference among varieties with similar AC. Rice varieties with higher AC usually have more long branches of amylopectin, which leach less when cooking, leading to higher hardness, lower stickiness, and less panelist preference [54]. Umemoto et al. suggested that the distributions of the short-length chains (DP ≤ 11) of amylopectin and the intermediatelength chains (DP 12-24) in varied rice varieties were different, while the number of long-length chains (DP ≥ 25) was similar [73,74]. The ACR of ΣDP ≤ 11/ΣDP ≤ 24 was seen as the basis for classification according to the actual differences in the chain length as well as chain-length distribution in different rice varieties [75]. All amylopectin varieties can be classified into the following types: type I and type II. The ACR of type I amylopectin was lower than 0.22, while the ACR of type II amylopectin was more than 0.26. The ratio of amylopectin medium chains with DP 13-24 for the hybrid combinations with poor taste values was lower than that for the hybrid combinations with good taste values [76]. However, the ratio of amylopectin short chains with DP 6-10 for the hybrid combinations with poor taste values was larger than that for the hybrid combinations with good taste values. Rice varieties with higher BDV and lower CSV, SBV, CPV, HPV, PaT, and PeT are considered to have higher grain quality, better viscosity, softer texture, and better cold rice texture [75]. Glutinous rice varieties with a lower distribution of intermediate and long chains and a greater distribution of short chains in amylopectin structure brought about lower RVA spectrum characteristic values and GT [77]. Specifically, the distribution of amylopectin short chains with DP 6-11 in glutinous rice varieties had remarkable and negative correlation with CSV, CPV, HPV, PKV, PeT, and PaT. The distribution of intermediate-long chains ranging from DP 12 to 24 was significantly positively correlated with CSV, CPV, HPV, PaT, and PeT. Amylopectin long chains with DP 25-36 also had significant and negative correlation with PaT. Previous studies found that chemically isolated rice amylopectin produced three kinds of anhydro glucose chain populations (long B, medium-B, and A plus short B) upon debranching [78][79][80]. In most of research mentioned above, the stickiness had negative correlation with the stiffness or firmness. Generally, stickiness is attributed to amylopectin, particularly the short chains of amylopectin (A and short B chains) [80][81][82]. The increase in the proportion of amylopectin short chains produces greater opportunities for bonding and molecular interaction; hence, more force is needed to separate the granules, eventually resulting in higher stickiness [16]. The decreased amylopectin medium chains (DP 13-24) as well as the higher number of short chains (DP 6-12) will lead to more amylopectin leaching during RVA measurement, therefore causing higher viscosity [83]. Hybrid rice with more amylopectin long chains has a harder texture when cooked [76]. The larger proportions of amylopectin long chains inhibit the swelling and gelatinization of starch particles, bringing about poor taste values of hybrid rice. Amylose-lipid compounds can form an insoluble layer around the particles to prevent the entry of water [84]. The long amylopectin chains interact with other ingredients in rice grains, including lipids, proteins, and non-starch polysaccharides, leading to a harder texture and restricting the swelling of starch [82,85]. In addition, a longer lipid chain length as well as higher concentration leads to delayed pasting and gelatinization of starch suspension, leading to a firmer cooked rice texture, whereas a short chain has the reverse effect [86]. Moreover, Peng et al. reported, for the first time, that the larger diversity of sizes and forms of starch granules might affect hybrid rice eating quality [76]. Larger native starch particles would have much more bonding points with water, which benefits the uptake of more water during cooking, and thus reducing the hardness [87].
The biosynthesis of rice starch involves numerous enzymes, including GBSSI, SSS, AGPase, DBE, and SBE [88][89][90]. Each enzyme is encoded by a corresponding gene. To date, more than 20 genes associated with starch biosynthesis have been found, including genes that encode AGPase subunits AGPlar, AGPis, AGPsma; multiple genes generated by different splicing modes, genes that encoding starch synthase, including GBSSII, SSI, SSIIa, SSIIb, SSIIc, SSIIIa, SSIIIb, SSIVa, SSIVb, and Wx; genes that encode debranching enzymes ISA, PUL; and genes that encode starch branching enzymes SBE1, SBE3, SBE4 [91][92][93]. The Wx gene is the major decisive factor of AC and performs a determining role in rice ECQ [26]. So far, a series of Wx alleles have been reported, such as Wx, Wx lv , Wx in , Wx a , Wx b , Wx mw/la , Wx op/hp , Wx mp , and Wx mq [94][95][96][97][98]. In normal rice varieties, high AC level (>25%) are decided by the Wx lv and Wx a alleles; nevertheless, the Wx lv allele was recognized as the ancestor type of the Wx gene, conducing to a higher AC level than that of the Wx a allele [99]. With regard to other Wx alleles, Wx mp , Wx mq , and Wx op/hp conduce to a very low AC level (8-12%); Wx mw/la results in a low AC (about 14%); Wx b also leads to a low AC (about 15%); Wx in contributes to a medium AC (about 20%) [94,97,98,100]. Feng et al. also confirmed that rice carrying Wx lv allele tends to have larger AC than rice carrying other Wx alleles [99]. The allele Wx b (usually exists in japonica cultivars) is a low-amylose allele along with soft texture [101]. The Wx a allele (mainly distributed in indica cultivars) has a higher AC as well as a firmer cooked rice texture. The AC of Wx a was significantly higher than that of Wx b . In terms of RVA parameters, SBV, CPV, and HPV were higher in rice carrying Wx a than those in rice with Wx b , while BDV and PKV were lower in rice with allele Wx a than those in rice carrying Wx b [102]. In regards to the GT, the values of Tc, Tp, and To of the rice with Wx a allele were slightly lower than those carrying the Wx b allele, which suggested that Wx was at least a secondary factor affecting the GT. Compared with rice with the Wx a and Wx b alleles, rice carrying the allele Wx lv had higher AC but softer GC [99]. Starch synthase gene SSIIa is the major gene controlling rice GT, and Umemoto et al. located the SSIIa gene at the ALK site of the short arm of rice chromosome 6 [74]. The alleles SSIIa and SSIIIa derived from a non-semi waxy parent showed a trend of increasing AC. SSIIa wj allele could enhance the BDV, CPV, HPV, and PKV, while reducing the SBV and CSV. In regard to the SSIIIa wj allele, the opposite was true [26]. Luo et al. proved that in the inbred line population of Nip and IR64, the SSI j allele engendered fewer short amylopectin chains (DP 8-12) than the SSI i allele [103]. Wx and SSIIa genes have great interaction effects on starch physicochemical characteristics. Huang et al. demonstrated that in transgenic rice, the expression of Wx was declined with SSIIa expression inhibited by RNAi, suggesting that there was an interaction between SSIIa and Wx expression [104]. When cooked rice was warm, the taste value of grains from Nip (Wx b /SSI j ) was significantly higher than Nip (Wx b /SSI i ), and gains from waxy rice had a similar taste value [105]. In addition, SSIV-2, ISA, and SBE3 are secondary genes that influenced GT additively [76].

Protein
Although there is a positive correlation between amylose content and cooked rice hardness, the physical characteristics of Chinese cooked rice are primarily affected by its PC. The structure and content of starch decide the overall stiffness of cooked rice, while protein determines rice surface hardness [106]. Protein is the second most significant ingredient of rice after starch, with a content of about 40-180 g kg −1 [107,108]. Grain PC varies depending on rice varieties, ranging from 5.9% to 16.5% in japonica rice and from 4.9% to 19.3% in indica rice [109]. Rice PC is one of the most vital factors affecting ECQ. Although the PC of rice determines the nutritional quality, it also has a negative impact on cooking features by affecting the cohesiveness and hardness of grain. Low-PC rice usually has better eating quality [110][111][112][113]. Previous studies implied that higher PC seriously decreased the rice taste value, which might be due to the fact that PC is highly negatively correlated with BDV and PKV and positively correlated with hardness [14]. When grain PC surpasses 7%, the ECQ of rice tends to decline [114,115]. Li et al. also found that the japonica rice with the highest taste value had the lowest AC, SBV, and PC [116]. Proteins themselves have no flavor in rice substrate, but amino acids, the base unit of protein, can provide abundant precursors for rice aroma formation. The volatile sulfur-containing compounds generated by protein oxidation or decomposition during heating, such as dimethyl sulfide and hydrogen sulfide, can also influence rice aroma [117]. Moreover, Yanova et al. reported that PC directly influences the hygroscopicity of rice grains [118]. High PC, few gaps between starch grains, compact structure of rice grains, less water absorption, and slow water absorption lead to longer cooking time, insufficient starch gelatinization, lower viscosity, and looser texture of rice [119]. Protein contends with starch for water during the cooking process of rice [120,121], and limits the swelling of rice starch granules through forming disulfide-bond networks [112,122]. Meanwhile, the denatured protein forms a gel matrix after heating, which strengthens starch integrity, thus decreasing the viscosity and enhancing the hardness of cooked rice [123]. Asimi et al. evaluated 12 newly bred rice varieties and found that the hardness of H2-73 was significantly higher than other rice samples due to its high PC and AC [119]. The PC in each layer of low eating quality rice was higher than that of high eating quality rice, particularly in the outer layer [124]. Rice outer layer was the main channel for water to enter the rice interior, and excessive PC in the rice outer layer may inhibit water absorption of rice [125]. Additionally, high PC impedes starch pasting [126]. Hence, it may be hard for heat and moisture to enter the rice interior, ultimately resulting in worse rice eating quality.
SSPs constitute a large proportion of grain proteins in rice [127]. There are four types of rice grain SSPs with different solubility-related physical characteristics: prolamin, albumin, glutelin, and globulin. Each of these protein fractions exhibit different levels of aqueous solubility, thus it is possible that they affect the quality of rice by having an influence on starch hydration rate during cooking [107]. The content, distribution, and features of the four types of SSPs in rice are quite different, leading to different effects on rice eating quality [128]. Globulin and albumin are distributed at the outer regions of rice endosperm, while glutelin are stored towards the center. On the contrary, prolamin is distributed evenly in the whole rice endosperm [129]. Glutelin is abundant in essential amino acids and is the richest SSP, accounting for about 80% of total SSPs. Zhang et al. found that the contents of glutelin and prolamin were lower but albumin content was higher in varieties with higher eating quality [130]. Rice prolamin and glutelin contents could enhance or decline together, and the content of albumin is significantly negatively correlated with AC [131,132]. Compared with the medium-AC varieties, the low-AC varieties usually have a higher albumin content. These results indicated that decreased prolamin and glutelin contents and enhanced albumin content could greatly improve the ECQ of rice despite rice glutelin being widely considered to have higher nutritional value in contrast to other storage proteins [88,130]. Balindong et al. found a significant correlation between eating quality and protein compositions of rice with two grain shapes, and reported that the total content of prolamin and the ratio of prolamin/(glutelin + prolamin) were positively correlated with pasting properties [107]. However, they also indicated that globulin exhibited very low levels of variation between and within different kinds of rice, which reflected in their little to no correlation with the texture analyzer or RVA parameters. Globulins are synthesized at the early stage of rice grain development and may function as structural proteins to maintain the integrity of protein body [133,134], and this may be the reason responsible for their low level of variation.
Protein in rice gains can interact with starch to form a network structure, resulting in increased starch solubility and swelling, decreased TV and PKV, enhanced SBV and PaT, containment of starch gelatinization, and declined viscosity of rice after cooking [134]. The generation of disulfide bonds enhanced the level of cross-linking between starch and protein, allowing the protein to form strong networks around the starch, restricting starch expansion [135]. When observing the interaction between starch and glutelin, the hydrophobic amino acids and hydrophilic groups in glutelin adhere to the surface of the starch granule through hydrophobic interactions or hydrogen bonds [136]. This interaction could affect the structure of starch granules and influence its gelatinization. The higher prolamin content is related to higher BDV but lower gumminess, adhesiveness, and stiffness of the gel generated from the flour, whereas albumin is positively related to gel hardness, pasting viscosity, BDV, and FV, but negatively linked with gel adhesiveness [137,138]. Moreover, coordinating the balance between protein and amylose is the key to enhance rice eating quality. Yan et al. revealed that when the AC in conventional japonica rice varied from 13.9% to 19.4%, there was a remarkable negative correlation between PC and eating quality [139]. Liu et al. reported that when AC changed in the narrow range, for example, 7.35-12.50% or 14.11-19.98%, eating properties had no significant correlation with AC, and instead they were significantly correlated with PC [140]. This suggested that eating characteristics are mainly affected by PC when AC varies within a narrow range. When PC varied in wide range (6.04-9.32%), it was significantly correlated with eating properties. However, when PC spanned in a range (7.86-9.32%), the impact of PC on eating quality was not significant. These studies indicate that the variation ranges of AC and PC may affect the relationships among PC, AC, and eating quality. In addition, Liu et al. also found that in order to improve rice eating quality (taste value > 60), the PC in high AC type varieties (14.11-19.98%) should be lower than 6.98%, and the AC in high PC type varieties (7.86-9.32%) should be less than 12.67% [140].

Lipid
Lipid is one of the three major essential nutritional ingredients in rice grains, with milled and brown rice having 0.8% and 3% lipid contents, respectively [141,142]. Although lipid content is low in rice, it is important in energy storage, cell membrane components, and signal transduction [143,144]. Rice lipids are mainly distributed in the embryo, with a content of 34.1-36.5%, followed by aleurone layer and endosperm, with a lipid content of 19.4-25.5% and 0.41-0.81%, respectively [145]. Lipid is a vital nutrient that surrounds starch particles in rice and can interact with amylose during starch gelatinization. It is usually bound with amylose and amylopectin to form complexes, and thus, affect GC and the viscosity of rice elasticity and texture [146]. Rice with higher lipid content had a brighter luster and better eating quality [147]. The role of rice lipids was studied in the variety Koshihikari planted in two places, wherein the removal of lipids was found to enhance the firmness of cooked rice [148]. Fitzgerald et al. investigated the effect of rice lipids on RVA characteristics, and found that the main role of lipids in RVA properties in rice was to change PKV and FV, possibly due to the release of more amylose through the loss of amylose-lipid compounds upon degreasing [149]. Moreover, the combination of protein and lipid peroxide formed by the automatic oxidation of UFAs reduces the solubility of protein [150,151]. In the lipid system, lipid can affect the release and volatilization of aroma by reducing the vapor pressure of aroma compounds, hence changing the release time and headspace concentration. Bi et al. found that the addition of edible oil in cooked rice weakened aroma release during consumption, whereas the taste of rice was more mellow, possibly because lipids retained more aroma compounds in cooked rice [152].
Lipids are usually be divided into two categories, non-starch lipids and starch lipids (bound lipids), according to whether they bound with starch or not. Non-starch lipids including glycerophospholipids (phosphatidylinositol, phosphatidylethanolamine, phosphatidylcholine, and their lyso form) and glycerolipids (triglyceride and diglyceride) are mainly present in the oil bodies of embryo and the aleurone layer, while starch lipids bound with starch particles exist in the rice endosperm [153,154]. Starch lipids, mainly composed of free FA and lysophospholipid, play a vital role in the biosynthesis of starch and thereby affect rice ECQ [145]. Previous studies have indicated that compared to starch and protein contents of rice grain, the lipid content, particularly the starch lipid content of milled rice, had a remarkable impact on rice ECQ, which enhances with the increase in the starch lipid content of milled rice [155,156]. Studies also reported that starch lipids in rice have a greater impact on rice eating quality than non-starch lipids [157]. Starch lipids complexes, formed during heating-cooling process or in natural starches, decreased starch solubility, and gelatinization [158,159]. Lipids and amylose compounds formed during cooking can entangle with amylopectin molecules and limit the swelling of particles, leading to incomplete gelatinization during cooking, which causes a lower PKV and a higher PaT [160,161]. Zhang et al. observed a significant enhancement in pasting viscosity via removing both starch lipids and non-starch lipids instead of taking out non-starch lipid only [162]. In addition, the presence of rice starch lipids can impede the contact of starch particles with digestive enzymes, and thereby decrease the digestibility of starch particles [126].
Lipids are resolved by lipase into FA and glycerin. Most of the FA ingredients are high-quality UFAs, accounting for about 75% of rice total FAs. They not only have great nutritional value, but also are closely related to the ECQ of rice [34,153,163,164]. It was reported that lipids content, particularly the content of unsaturated lipid, is positively correlated with the fragrance and overall quality of rice [165,166]. Increasing UFAs content can significantly enhance rice eating quality.

Nitrogen Fertilizer Affecting Rice Eating Quality
In addition to intrinsic ingredients, the eating quality of rice is also greatly affected by nitrogen fertilizer (Table 3). In general, as a vital cultivation measure, the application of nitrogen fertilizer can enhance rice yield, but it decreases the ECQ of rice. Many studies showed that the contents of protein and amino acid in rice is enhanced with nitrogen application rate, whereas starch and amylose contents are reduced accordingly [113,167,168]. Jiang et al. demonstrated that panicle nitrogen fertilizer degraded the ECQ of inferior and superior grains of japonica rice, which enhanced the hardness, reduced taste value, and deteriorated pasting properties. This was associated with the fact that panicle nitrogen fertilizer improved PC and declined starch and crude fat content [169]. Through a two-year experiment, Zhao et al. found that excessive nitrogen decreased the average and maximum grain filling rate of inferior grains and superior grains of japonica rice and lengthened the active period of grain filling, and deteriorated the ECQ, suggesting that excessive nitrogen causes the lower rice grain quality by inhibiting grain filling. Compared with superior grains, the quality parameters of inferior grains were more sensitive to nitrogen fertilizer [170]. However, some studies proved that the responses of rice starch to nitrogen fertilizer varied among varieties. Hu et al. investigated the responses of the quality of two rice varieties to nitrogen application. They found that the BDV and PKV of giant embryo rice (J20) reduced and its PaT and SBV improved with increasing nitrogen, whereas Koshihikari had an opposite trend, but the contents of protein and protein component of both varieties were enhanced with increasing nitrogen, with gliadin being the most sensitive protein ingredient to nitrogen fertilizer [171]. Therefore, the nitrogen fertilizer treatment suitable for different rice varieties should not be the same. Developing cultivation measures based on specific varieties and needs can greatly meet the needs of high yield and quality in rice production.  Taste value of superior and inferior grains of japonica rice reduced, while hardness and stickiness increased.
The content of total starch, amylose, amylopectin and the ratio of amylose/amylopectin decreased. The crude fat content decreased but had an insensitive response to the gradient of N. Total protein and protein component contents increased.
The increase in total protein content by PNF was mainly related to prolamin and glutenin.
The proportion of small and medium starch granules increased, while the proportion of large starch granules decreased. The starch volume mean diameter decreased. A chain content decreased, and B2 chain and B3 chain contents increased, the average chain length of amylopectin increased and (A + B1)/(B2 + B3) decreased.
Starch relative crystallinity increased. The starch amorphous region and single helix content decreased, and the double helix content increased. Starch solubility and swelling power improved.
The PKV, hot viscosity, and FV decreased. The SBV decreased in the beginning and then increased, and the PaT increased, while the BDV showed few differences. The ∆H increased, and the retrogradation enthalpy and percentage decreased.
AC decreased, protein component content increased.
-The viscosity, balance, and gel consistency decreased.
More protein bodies surrounding the amyloplasts. Compared with N0, rice at N1 at 0 min had more large granular matter, and there was some granular matter around the large amyloplasts. Rice protein had more β-sheets.
The PKV and BDV decreased. After cooking for 10 min, almost all amyloplast were converted into starch paste at N0, but some amyloplast was still structurally intact at N1. As the cooking time increased, the starch began to gelatinize, and more amyloplasts became flat and smooth.
At N1, it still showed more considerable flat material. Nitrogen treatment had no significant influence on the secondary structure of glutelin, globulin, and albumin. Compared with N1, N4, and N5 significantly decreased the ratio of α-helix of prolamin.
With the increasing N rate, PKV, TV, and FV first increased and then decreased, and the peak value appeared at N2. Compared with N1, N4 and N5 reduced the viscosity index. With increased N rate, rice swelling rate and softness increased at first and then decreased, achieving the highest point at N2. The changes in starch structure and protein distribution significantly affect rice eating quality. With the enhancement of nitrogen rate, the mean diameter of starch volume was lower; the average chain length of amylopectin was longer; and the starch relative crystallinity was higher. The above changes in starch structure caused increased starch solubility, expansion power, and gelatinization enthalpy, and resulted in reduced pasting viscosity, retrogradation enthalpy, and retrogradation percentage, thereby contributing to enhanced stickiness and hardness of rice and decreased taste value [169]. Nitrogen fertilizer largely improved PC in rice outer layer, and the increase in the outer layer was significantly larger than those in rice middle and inner layer with increasing nitrogen rates [125]. During cooking, the rice outer layer directly contacts water. More protein content in the rice outer layer could restrain water absorption, which may make the rice outer layer difficult to gelatinize, which eventually affects rice eating quality. Additionally, high nitrogen rate causes more protein to stick around the amyloplasts, shaping a honeycomb structure, and this suppresses starch gelatinization during cooking [172]. Moreover, under high nitrogen rate, the protein in rice has more β-sheets, which can retard the rate of water entering into the starch interior and avoid the devastation of short-range ordered structure of starch.
Although nitrogen application decreases rice eating quality, some types of nitrogen fertilizers can increase the quality to a certain extent compared with conventional urea. In recent years, CRNF has been widely used in cereal crops such as maize, wheat, and rice as a novel, environmentally friendly, and effective fertilizer [174]. It can slowly release nitrogen into the soil throughout various growth periods to guarantee a continuous supply of nitrogen during crop growth [175]. Zhao et al. investigated the effects of the combined application of normal urea and controlled release urea (at different nitrogen ratios) on the yield, grain quality, and nitrogen efficiency of rice. They obtained a lower hardness of cooked rice treated with controlled release urea compared with that treated with fractionated urea [176]. It was reported by Wei et al. that the CPV, HPV, BDV, PKV, and CSV of rice under the treatments of slow or controlled release fertilizer were higher than those under common urea; and GC, CPV, HPV, and PKV were all positively correlated with viscosity, taste value, and appearance, while BDV and PKV were negatively related to hardness of cooked rice [177]. Xu et al. also found that milled rice starch content, MQ, AQ, as well as the taste value of rice treatment with CRNF were significantly larger than conventional urea, while glutenin, gliadin, and protein contents and hardness of rice had the reverse trends [178]. The higher PC in rice treated with conventional urea led to higher GT and firmer rice, which may be the reason that rice ECQ in the conventional urea was lower than that in the CRNF treatment. Liu et al. demonstrated that a controlled release fertilizer treatment produced higher PC in rice than no fertilizer treatment, but differently to the above studies, they observed that rice treated with controlled release fertilizer had lower rice AC compared with no and conventional fertilizer [179]. The relative improvement of nitrogen metabolism in a single rice cultivar with varied fertilizer treatments tends to inhibit the carbon metabolism during grain filling [180]. Thereby, slow or controlled release fertilizer or fertilization mode with continuous release of nitrogen, especially at the late growth stage of rice, had a tendency to enhance protein content while reducing amylopectin, amylose, and starch contents [177]. Adopting appropriate fertilizer types and fertilizer operations can improve rice ECQ while ensuring high yield, which can meet the goal of highly efficient and high-quality rice production.

Conclusions and Future Perspectives
The quality of rice is crucial for its commercial value. With the improvement of people's living standards, new requirements have been put forward for rice ECQ. High quality rice varieties need to have good ECQ on the premise of high yield. For a long time, rice production has focused on increasing yield, and the research on the rice quality has started relatively late, especially in terms of ECQ. Among the multiple indicators used to measure rice quality, ECQ is the most complex. Generally, artificial taste or indirect traits such as AC, PC, and RVA values are used to evaluate rice ECQ. Starch is the most important component in rice, accounting for about 90% of milled rice. Therefore, the content, structure, and distribution of starch are closely related to rice ECQ. Protein is the second most abundant component in rice, and more and more studies have shown that protein has a significant impact on grain water absorption and starch gelatinization during the cooking process. Lipid is one of the three basic nutritional components in rice. Although lipid content in rice is low, it significantly regulates the elasticity, viscosity, and texture of rice. Hence, in evaluating rice ECQ, one cannot solely rely on a single indicator or method. We should start from the physical and chemical foundation of rice itself, combine the results from artificial taste and various testing instruments, and consider the preferences of people in different regions to evaluate the ECQ of rice more scientifically and systematically.
Rice ECQ is mainly influenced by factors such as genetics, environmental factors, and cultivation measures. Nitrogen application is an important agronomic measure in rice production and has an impact on the formation of rice quality, especially when it is applied after the heading stage. Further exploration of the responses of rice physicochemical indicators and ECQ to nitrogen fertilizer is of great significance for revealing the physicochemical mechanisms underlying the formation of rice ECQ and the mechanisms by which nitrogen regulates rice ECQ. Recent studies have shown that rice yield and ECQ are extremely sensitive to different nitrogen regulation practices. Nitrogen fertilizer affects the growth and development of rice and regulates rice physiological and biochemical metabolism, which not only affects the content of various physical and chemical substances in mature grains, but also has a significant impact on the structure and distribution of each physical and chemical substance in the grains. It is generally believed that the application of nitrogen fertilizer can reduce rice ECQ, but the physiological mechanisms of quality deterioration in different rice varieties after nitrogen application may not be the same. This provides us with a new idea that the combination of suitable varieties and matching fertilizers may not significantly affect rice ECQ while increasing yield. Therefore, in the future work of promoting varieties and popularizing cultivation measures, matching varieties and fertilizer management as a whole is a new strategy to achieve both high yield and good ECQ in rice production.

Data Availability Statement:
No new data were created or analyzed in this study. Data sharing is not applicable to this article.

Conflicts of Interest:
The authors declare that the research was conducted in the absence of any commercial or financial relationship that could be construed as a potential conflict of interest.