Profiling of Volatile Organic Compounds (VOCs) of Wild Edible Durians from Sarawak, Borneo Associated with Its Aroma Properties
1
Department of Crop Science, Faculty of Agricultural and Forestry Sciences, Universiti Putra Malaysia Bintulu Sarawak Campus, Bintulu 97008, Sarawak, Malaysia
2
Institut Ekosains Borneo, Universiti Putra Malaysia Bintulu Sarawak Campus, Bintulu 97008, Sarawak, Malaysia
3
Faculty of Health and Life Sciences, INTI International University, Nilai 71800, Negeri Sembilan, Malaysia
*
Author to whom correspondence should be addressed.
Horticulturae 2023, 9(2), 257; https://0-doi-org.brum.beds.ac.uk/10.3390/horticulturae9020257
Submission received: 11 January 2023
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Revised: 8 February 2023
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Accepted: 13 February 2023
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Published: 15 February 2023
(This article belongs to the Special Issue Physico-Chemical Characterization of Fruits and Vegetables)
Abstract
:Volatile organic compounds determine the aroma properties of durian, and it is an important factor in durian acceptance by consumers. However, limited information is devoted to volatile organic compounds and aroma in wild edible durians. Therefore, the present study aims to characterize and compare the volatile organic compounds and aroma properties of the indigenous wild edible durians from Sarawak, Borneo. Seven genotypes, namely Durio dulcis, Durio graveolens (yellow-fleshed), Durio graveolens (orange-fleshed), Durio graveolens (red-fleshed), Durio kutejensis, Durio oxleyanus, and Durio zibethinus were characterized in this study. Solid phase microextraction combined with gas chromatography-mass spectrometry (SPME GC-MS) was used to detect the volatile organic compounds, while the quantitative descriptive analysis (QDA) method was used to characterize the aroma properties of wild edible durians. A total of 119 volatile organic compounds comprising alcohol, aldehyde, amine, ether, ester, ketone, nitrogen-containing, and sulfur-containing compounds were detected. Ester and alcohol compounds are the most predominant in the composition, especially D. graveolens (yellow- and orange-fleshed), and D. dulcis possessed three to nine times higher relative amount of ester compounds. PCA clearly classified the wild durians into different groups. Based on the QDA analysis, D. kutejensis has the mildest aroma among wild edible durians, while D. dulcis perceived a stronger sweet and grassy aroma. Partially Least Square (PLS) regression model analysis indicated a strong relationship between the volatile organic compounds and the aroma intensity perceived by the panelists. These findings could be the major component in the durian industry, paving the way for breeding efforts to create new cultivars that can improve consumers’ satisfaction.
1. Introduction
Durian (Durio sp.) is known as the ‘King of Fruits’ that grow seasonally in tropical Asia, gaining worldwide attention with its iconic intimidating spiky husk. Besides its admirable flavour, durian is also well-known for the offensive smell that could be overpoweringly unpleasant to those unfamiliar with it. Durian’s offensive smell has been described as abominable; an offensive blend of aged cheese and onions with turpentine flavouring [1]. However, the demand for durians has surged as more consumers express interest in this delicacy with a distinctive flavour, making the durian industry more alluring for global importers and exporters. According to Tridge Intelligence [2], Thailand is the biggest exporter of durians, responsible for 46.7% of global exports taking the total to a USD 689.43 million export value. Hong Kong overtook China to take over as the top importer of durians in the same year, with 224.22 million metric tons of imports totalling USD 717.37 million. China’s participation in the Regional Comprehensive Economic Partnership (RCEP), which is the world’s largest trade bloc, accounting for 30% of the world’s Gross Domestic Product (GDP), has made it easier for China to import fresh fruits from Southeast Asian nations such as Thailand, Malaysia, and Indonesia, the three-leading durian-producing countries [3]. In Malaysia, due to its potential to create new revenue streams for local farmers, durian is regarded as a gold commodity for agriculture in the future [4].
At present, the genus Durio consists of approximately 30 species worldwide, of which only ten species produce edible fruits, i.e., Durio dulcis, Durio graveolens, Durio grandiflorus, Durio kutejensis, Durio kinabaluensis, Durio lowianus, Durio oblongus, Durio oxleyanus, Durio testudinarius, and Durio zibethinus while the remaining species produce either extremely unpalatable (inedible) or arilles fruits [5,6]. The island of Borneo is the center of Durio distribution, where Kalimantan has the highest diversity of Durio with 18 endemic species [7], while Sabah and Sarawak have 14 and 16 Durio species, respectively [8,9]. Durio zibethinus, is the most economically significant and widely cultivated [10], while the other edible durian still occurs wild in the tropical forest [5], and some may face the danger of extinction or may already be extinct. In Sarawak, the indigenous edible durians of D. graveolens (isu), D. kutejensis (nyekak), D. oxleyanus (durian daun), and D. zibethinus (durian kampung) are domesticated and widely sold at Tamu markets at a good fetching price. These indigenous species could provide a steady source of nutrition and income for local people in rural areas. The other indigenous edible species of Durio are still found in the wild, but occasionally they can be found semi-domesticated. The wild edible Durio species are equally valuable to D. zibethinus as they have the potential as fruits tree crops themselves, although not widely grown near the scale of D. zibethinus. Brown [11], Subhadrabandhu and Ketsa [12] and Susilawati et al. [13] stated that these wild Durio species have superior quality traits as they have high aesthetic value in terms of their pericarp and aril colours, unique taste and aroma, and some of the species have high disease resistances. These local durians are diverse in shape, taste, and smell, which holds great promise for future domestication.
The aroma of durian was controversial since long ago, which is often described as a fruity, offensive, and onion-like odor due to the presence of volatile esters and sulfur-containing compounds [14]. Fruit aroma is an important factor in durian acceptance by consumers [4]. In fact, taste and aroma influence each other, and aroma is considered a fundamental component of fruit flavour [15]. Fruit aromas differ noticeably due to variations in the composition and content of volatile organic compounds (VOCs). Solid phase microextraction (SPME) is frequently utilized in extracting fruit aromas as it requires less time, is easy, and is solvent-free [15]. In recent years, volatiles emitted from durian were studied by using solid-phase microextraction combined with gas chromatography-mass spectrometry (SPME GC-MS) [4,15,16].
To date, there were numerous studies published on the volatile organic compound profiling of D. zibethinus and its cultivars [14,15,17,18,19]. To the best of our knowledge, information devoted to volatile organic compounds and their aroma on wild edible durians is still limited. The edible wild durian is known to be varied uniquely with its aroma and taste. Furthermore, understanding these VOCs is important because durian is valued for its distinct flavour and aroma. These traits of the wild edible durians need to be explored more, as these might open a new opportunity for the plant breeder to develop new cultivars. Therefore, this study aims to characterize and compare the volatile organic compounds and aroma characteristics of several wild edible durians indigenous to Sarawak, Borneo. The findings of this study can be utilized as the basis for developing new durian cultivars that will increase their favorability and appeal to a larger spectrum of global customers.
2. Materials and Methods
2.1. Sampling Area and Samples Collection
Sampling was conducted during the durian season (from August 2021 to March 2022) in several rural areas within the northeast to central regions of Sarawak, including Bekenu, Niah, Baram, Sibu, and Tatau (Figure 1). The coordinate of each location (Table 1) was marked using Garmin GPS Handheld (GPSMAP79S, Olathe, KS, USA). Twenty-five ripe fruits of D. dulcis, D. graveolens (yellow-fleshed), D. graveolens (orange-fleshed), D. graveolens (red–fleshed), and D. kutejensis, and 15 fruits of D. oxleyanus, and D. zibethinus that dropped naturally were collected. Fruits were selected for uniformity in size and free of diseases and visual defects. The samples were immediately transported to the laboratory and dehusked (the rind was cut open) the same day prior to analyses. Durian pulps that free of visual defects were selected for further analysis.
2.2. Fruit Morphology
The morphological characterization of the durian fruit was carried out following the guidelines based on Descriptors Durian (Durio zibethinus) by Bioversity International [20]. Six qualitative and four quantitative parameters of the fruit were measured using a ruler, vernier caliper, and laboratory weighing scale.
2.3. Volatile Organic Compounds (VOCs) Analysis
2.3.1. Volatile Organic Compound Extraction Using Solid Phase Microextraction (SPME)
Sample preparation was carried out according to Chin et al. (2007) [19] with slight modifications. 50 g of fresh durian pulps were blended to create homogenate with 100 mL of cooled ice water for 1 min. 10 mL of the blended pulp was transferred into a 30 mL vial together with a magnetic stirring bar and 5 g of sodium chloride. Before the vial was crimped-sealed with 20 mm diameter aluminum seal with Teflon septum, internal standard 100 μL thiophene (10 ppm) was spiked into the sample. The homogenate was kept under constant vigorous stirring at 30 °C for 1 h in a water bath. Then, the SPME syringe was manually inserted into the headspace of the vial with the fiber coating exposed for 30 min. A 50/30 µm divinylbenzene/carboxen on polydimethylsilxane (DVB/CAR/PDMS) fiber was used to extract volatile organic compounds from durian samples.
2.3.2. Volatile Organic Compounds (VOCs) Analysis Using Gas Chromatography-Mass Spectrometry (GC-MS)
The separation was performed using a gas chromatography (GC) system (Agilent 7890A) directly coupled with a mass spectrometer (MS) system of an Agilent 5975C insert MSD with a triple-axis detector as described by Belgis et al. [16]. The analysis was performed in a BP20 (WAX) analytical column (30 m × 0.25 × 0.25 µm film thickness). The injector temperature was held at 240 °C. The injection port was operated at splitless mode with purified helium as the carrier gas flowing at 0.4 mL/min. The oven temperature was set isothermal at 40 °C for 1.5 min, ramped to 240 °C at 50 °C/min, and then held at this temperature for 2 min. The interface temperature was 240 °C, and the ionizing voltage was 70 ev. The MSD Chemstation was used to identify all the peaks in the raw GC chromatogram. A library search was carried out for all the peaks using the NIST/EPA/NIH version 2.0, and the results were combined in a single peak table. Quantification was carried out by comparing peak areas of analytes to that of thiophene added as an internal standard to the samples. Two replications were maintained in this experiment. The relative amount of VOCs was done by comparing the peak areas of the detected VOCs to the peak area of internal standard thiophene. The result was expressed as:
Relative amount of VOC = (Peak area/Internal standard area) × 1000
2.4. Aroma Characterization Using Quantitative Descriptive Analysis (QDA)
The Quantitative Descriptive Analysis (QDA®) method was used to characterize the aroma of the durian by training the sensory panels and carrying out the analysis according to the set sensory standards (ISO Standard 8586–2:1994). 15 trained panelists were screened and selected (2 sessions) for their sensory ability and trained (4 sessions) for descriptive analysis as described by Voon et al. [18]. The training was held for 1–2 h sessions a week for four weeks until satisfactory discrimination, reproducibility, and concept alignment were achieved. Reference standards are provided to help panelists with specific descriptors (Table 2). A sensory score sheet with 15 cm unstructured scale lines (0–15), each with anchored terms at both ends, was used to indicate the intensity of each attribute by placing a vertical line on the scale. The panels sat in individual booths and were asked to score the sensory properties of Durio species using seven different aroma sensory attributes, i.e., sweet, fruity, sulfury, alcohol, nutty, grassy, and floral. Three sessions were carried out to obtain the mean value for each sample. Panelists were provided water and an unsalted cracker to clear their palates between samples.
2.5. Statistical Analysis
The data on morphology variables were subjected to a one-way ANOVA following a Tukey test for comparisons of means (p < 0.05) using SAS window 9.4. Principal Compo-nent Analysis (PCA) was applied for species mapping based on their volatile organic compounds composition. Partial least squares (PLS) regression model analysis was conducted to study the correlation between volatile organic compounds and aroma characteristics. PCA and PLS analysis were performed using XLSTAT software (Addinsoft, New York, NY, USA).
3. Results and Discussion
3.1. Fruit Morphological Characterization
The seven wild edible Durio genotypes were diverse and unique in physical attributes compared to the common cultivars of D. zibethinus. This unique look of the wild edible durian makes it easily identified by the locals only by looking at its shape and size or even the spine shape. Among the studied wild durians, there were three genotypes under the species of D. graveolens, i.e., D. graveolens (isu kuning), D. graveolens (isu oren), and D. graveolens (isu merah), as they were named by the locals based on its pulp colour (yellow-fleshed, orange-fleshed and red-fleshed, respectively. Under the species of D. zibethinus, the local people have addressed this assession as durian kampung, also known as durian Terung iban.
The detailed fruit morphological characteristics are presented in Table 3. The exocarp of the seven genotypes varied from red, green, and yellow. Among the genotypes, the most attractive durian was D. dulcis, which the exocarp in red. Durio kutejensis and D. graveolens (red-fleshed) exhibited yellow exocarp, while D. graveolens (yellow- and orange-fleshed), D. oxleyanus, and D. zibethinus possessed green exocarp. This shows that the wild edible durian genotypes were very attractive compared to the common D. zibethinus, which appears green to pale green [21]. Durio graveolens species exhibited the most appealing pulp colour, which displays the colour yellow-fleshed, orange-fleshed, and red-fleshed. According to Susilawati et al. [13], the colour of the durian flesh generally has its own appeal in terms of the durian consumption rate. Apart from their aesthetic value, colouration in durian pulp (yellow, orange, and red) indicates that this fruit contains high carotenoids, anthocyanins, and polyphenols which is supported by Tan et al. [4], where Black Thorn possessed the reddish-orange pulp colour with highest total carotenoid content. The presence of carotenoids proves that the fruit has antioxidant properties that would benefit human health, such as eyes, brain, and heart health, as cancer prevention, UV protection, and immune stimulation [22,23].
The wild edible durian genotypes’ fruit shapes ranged from globose to obovoid, except D. kutejensis in obovate and D. zibethinus (terung iban) ovoid fruit shapes. This indicates that the indigenous edible durian from Sarawak exhibits an oblong to globose shape compared to the common durian cultivars, such as common durian cultivars in Malaysia, e.g., D197 (Musang King), D160 (Te Ka) and D175 (Udang Merah), mostly having oval to ellipsoidal [24]. The fruit base shape varied from flat to round, acute, round, and convex, extensively visualized. The Sarawak indigenous durian genotypes possesseda flat to round fruit base shape that is likely to be similar to the common Durio species.
The spine shape is an important parameter to look into detail that could differentiate the species or varieties [25], as some local Durio species have similar fruit colour, shapes, and sizes. Sujang et al. [26] reported that due to their physical similarity, D. graveolens and D. oxleyanus were created confusion among locals in Sarawak as both referred to as ‘isu’. However, they can be differentiated by their spine shape, where D. graveolens have a conical spine shape while D. oxleyanus possessed pyramidal with conical and sharply pointed spines. Durio zibethinus (Terung iban) exhibited a distantly arranged short spine with the shape of a pointed convex. It was observed that although the fruit size of D. kutejensis was smaller, the thickness of the arils (31.18 ± 5.41 mm) was comparable with the common D. zibethinus cultivars. Durio zibethinus (Terung iban) also possessed a significantly higher thickness at 30.65 ± 3.73 mm. This is contradicted by the D. dulcis, where the fruit size was significantly larger (p < 0.05) yet exhibited lesser aril thickness (5.75 ± 2.19 mm). Most of the indigenous edible durian was not easy to be opened as some of the appearances of the carpel are slightly distinct and indistinct such as D. dulcis, D. graveolens (yellow-, orange-, and red-fleshed) and D. oxleyanus. The hardest fruit to split is D. dulcis, which requires a cross-section method of splitting.
3.2. Compositions of Volatile Organic Compounds (VOCs) of Sarawak Wild Edible Durians
A total of 119 VOCs were identified in the genotypes, comprising 37 esters, 32 alcohols, 13 ketones, 10 ethers, 10 sulfur-containing compounds, 8 nitrogen-containing compounds, 5 aldehydes, and 4 amines. The composition of the VOCs in the seven genotypes of wild edible durians varies, as shown in Figure 2, and these differences determine the durians’ flavour and quality. The volatile organic compounds showed a great variation in different genotypes and ranged from 24 compounds in D. graveolens (Yellow-fleshed) and D. zibethinus (Terung iban) to 33 compounds in D. oxleyanus. The numerous VOCs that are present in durian contribute to its distinct scents. Ester compound was the highest percentage composition ranged 20% to 40%, followed by the alcohol compound ranged 8% to 36%. Most of the genotypes showed large composition with the ester compound followed by the alcohol compound except in D. kutejensis and D. zibethinus (Terung iban), as both genotypes have a higher composition of the alcohol compound followed by the ester compound. A total of 10 esters were identified in D. dulcis, D. graveolens (orange-fleshed), and D. oxleyanus. Followed by D. graveolens (yellow-fleshed) (9), D. graveolens (red-fleshed) (8), and with the least esters (5) in D. kutejensis and D. zibethinus (Terung iban). This contradicts the common durian cultivars of D2, D24, D101, MDUR78, CHUK, D88, D168, D175, D197, and D200, which possessed higher composition of sulfur compounds (9 to 15 compounds) as reported by Tan et al. [4], Xiao et al. [15], Voon et al. [18], and Chin et al. [19]. However, these wild edible durians exhibited the least composition of sulfur with 1 to 5 compounds. The present findings are in agreement with the volatile organic composition in the local durians of D. kutejensis (Batuah), which was predominantly by ester compounds (11), followed by alcohols (4), aldehydes (3), sulfurs and ketones (2) [16]. The presence of the nitrogen-containing compound was not detected in D. dulcis and the three genotypes of D. graveolens. Amine compounds only present, one to two compounds in D. graveolens (orange-fleshed), D. kutejensis, and D. oxleyanus.
3.3. Volatile Organic Compounds (VOCs) of Sarawak Wild Edible Durians
The identified volatiles and their relative amount in the respective genotypes are summarized in Table 4. The identified volatile organic compounds in durian genotypes were consistent with Tan et al. [4], Xiao et al. [15], Voon et al. [18], and Chin et al. [19]. and a few new compounds were identified for the first time in this study, as this is the first detailed profiling of all the wild edible durians in Sarawak.
Esters were the major compounds with almost 50% or surpass half of the relative amounts of VOCs in all the studied genotypes, except in D. graveolens (red-fleshed) (24.53%), D. kutejensis (8.83%) and D. oxleyanus (27.71%). Each genotype had different types of dominant esters, which may contribute to each genotype’s unique aroma characteristics. This can be seen in D. graveolens (yellow-fleshed) that butanoic acid, heptyl ester was the dominant ester compound, and D. graveolens (orange-fleshed) was the butanoic acid, butyl ester. Both of the compounds were described as giving fruity (pear, pineapple) and chamomile-like odor [27] (Table 4). Propanoic acid, 2-methyl, 3-methylbutyl ester compound can only be found in the three genotypes of D. graveolens that contributed to the sweet and fruity aroma. Durio kutejensis have the least amount of ester compounds, which was supported by Belgis et al. [16], where the lai cultivars from Indonesia (D. kutejensis) contained few esters, which explained the less intense fruity and sweet aroma. The study by Chin et al. [19] showed that ethyl-2-methylbutanoate is the major ester present in all (D101, D2, and D24) Malaysian durian cultivars, and this was in accordance with the present finding in D. zibethinus (Terung iban).
The second dominant VOCs was the alcohol compounds which account for 12% in D. zibethinus (Terung iban) to 48.92% in D. graveolens (red-fleshed). The three genotypes of D. graveolens have the highest relative amount to alcohol compounds, which were two times higher than the other genotypes. However, D. kutejensis had more diverse alcohols, although alcohols total relative amount of D. kutejensis was the third lowest among the seven genotypes. Several alcohols were only found in different durian genotypes and might also contribute to the nuanced aroma differences between the wild Durio species and common cultivars of D. zibethinus. 2-Furanmenthanol (burnt aroma) was the primary alcohol compound in D. graveolens (red-fleshed) and D. dulcis, but it does not present in D. zibethinus (Terung iban).
Sulfur-containing compounds were generally responsible for the distinct strong onion-like odor in durian fruit. Results revealed D. zibethinus (Terung iban) exhibited two (D. graveolens-red fleshed) to twenty (D. oxleyanus) times higher relative amout (37.66%) of sulfur-containing compounds. Diethyl disulfide and ethanethiol present in D. zibethinus (Terung iban), were also present in the D. zibethinus cultivars reported by Tan et al. [4] and Chin et al. [19]. Together with disulfide, ethyl 1-methylethyl, trisulfide, diethyl, and 1,2,4-Trithiolane,3,5-dimethyl-compounds found in this study might serve as character impact compounds in D. zibthenus that contributes to its strong sulfur note compared to other wild Durio species. A previous study by Belgis et al. [16] shows that the lai was less diverse sulfurs than durian cultivars, supporting this present work. The other genotypes, except for D. zibethinus, account for only 1.37% in D. oxleyanus to 10.15% in D. graveolens (red-fleshed). Moreover, it is found that 1-propanethiol, 2-methyl-compound is only present among the three genotypes of D. graveolens. Divinyl sulfide in D. graveolens (red-fleshed) in the least amount has been detected in several foods, especially onions.
Other compounds, such as nitrogen-containing compounds, ketones, aldehydes, amines, and ethers, were also detected in these wild edible durians. However, they only present in small amounts, or some are not in some genotypes. Nitrogen-containing compounds only was found in D. oxleyanus (38.91%), D. kutejensis (4.09%), and D. zibetinus (Terung iban) (2.75%). Ketones, aldehydes, amines, and ether compounds account for less than 10% of the relative amounts of the VOCs, or some of them are not detected in each genotype. There was no previous study that has reported on the presence of nitrogen-containing compounds in durians. Ketone and aldehyde compounds were reported to be present in durians by Tan et al. [4], Belgis et al. [16] and Voon et al. [18]. From the odor description in Table 4, aldehyde, ether, and ketone generally give fresh, fruity, floral, and ethereal odors, while amine and nitrogen-containing compounds possess ammonia-like, burnt-like, and fishy odor [27,28].
3.4. Principal Component Analysis (PCA) of the Volatile Organic Compounds (VOCs)
To explore the relationship between the volatile organic compounds profiles of samples from the various durian genotypes, principal component analysis (PCA) was performed to identify the grouping of the genotypes based on the correlation matrix. The finding revealed the first two principal components (PCs), PC1 (33.32%) and PC2 (29.20%), together accounted for 62.93% of the data variance. The result of PCA reveals that the seven genotypes were classified into five groups which can be seen in Figure 3. From the case projection on the factor plane (PC1 versus PC2), the PC1 axis distinguished D. dulcis that constituted a cluster on the positive side, while D. graveolens (yellow-fleshed), D. graveolens (orange-fleshed), D. graveolens (red-fleshed), D. kutejensis, D. oxleyanus, and D. zibethinus (Terung iban) spread at the negative side of PC1 axis.
Group 1 consists of D. dulcis alone on the positive side of the PC1 axis, as it has a high amount of aldehyde, ketone, and ether compounds. The ester compounds such as (E)-2-butenoic acid, ethyl ester; 2-methyl-2-butenoic acid, ethyl ester; 2-hydroxy-2 -methyl-butanoic acid, methyl ester; [R-(R*, R*)]-2,3-bis(acetyloxy), butanedioic acid; octanoic acid, ethyl ester, and methoxyacetic acid, 2-pentadecyl ester compounds were only present in D. dulcis. The presence of (E)-2-butenoic acid, ethyl ester, and octanoic acid, ethyl ester, which describe as having a pungent and sulfury odor, respectively, could explained the most ill-smelling of all Durio species that can be smelled for miles as stated by Soegeng-Reksodihardjo [8]. Moreover, D. dulcis also recorded the highest amount of 2-Furanmenthanol compound among the genotypes, where the compound gave a burnt odor. The two genotypes of D. graveolens, yellow-fleshed and orange-fleshed, were grouped on the positive side of PC2 (Group 2). This group was characterized as both genotypes having a similar presence of compounds such as alcohol, ester, and a small amount of ether, ketone, and sulfur but amine is not present in the yellow-fleshed genotype. Butanoic acid, heptyl ester, and butanoic acid, butyl ester had the highest relative amount in yellow- and orange-fleshed genotypes, which give a fruity odor [27,28].
Durio graveolens (red-fleshed), D. kutejensis, D. oxleyanus, and D. zibethinus located in negative PC2, were grouped into three groups. Durio graveolens (red-fleshed) in Group 3 was characterized by a mixture of mild aroma from alcohol, ester, and sulfur compounds and high relative amount of ketone and ether. The presence of ketone, ester, and ether compounds gives the durian a floral, fruity, and sweet odor. Durio kutejensis and D. oxleyanus grouped in Group 4 as they both perceived almost the same compounds. Alpha.-Aminooxy-propionic acid and ethyl ester compounds were only present in both genotypes of this group. However, D. oxleyanus has a high relative amount of nitrogen-containing compounds, such as tetramethylhydrazine and 2-ethyl-5-methyl-pyrazine, which might be responsible for the ammonia-like and nutty odor, respectively. This supports the report by Soegeng-Reksodihardjo [8] as they stated that D. oxleyanus was slightly fragrant but had a very tasty aril with a strong odor. Durio zibethinus alone, in Group 5, was characterized by a higher amount of sulfur-containing compound than other genotypes. Ethanethiol, diethyl disulfide, disulfide ethyl 1-methylethyl, trisulfide diethyl, and 3,5-dimethyl-1,2,4-Trithiolane were reported to be responsible for overpowering and roasty odor [28]. Thiol and sulfur were generally the most odorous aroma compounds and were found to be relatively high in all durian clones [19].
3.5. Sensory Analysis by Quantitative Descriptive Analysis (QDA)
The sensory evaluation was evaluated by 15 trained panelists, and the profiles of the 7 genotypes of wild edible durians are shown in Figure 4. The QDA result revealed that the genotypes varied in the intensity of sweet, fruit, sulfur, alcohol, nutty, grassy, and floral aroma attributes. The analysis showed that D. dulcis was characterized by the strongest sweet and grassy aroma. The panelist perceived D. kutejensis and D. oxleyanus as mild aroma durian. The research by Belgis et al. [16] found that D. kutejensis generally has a milder aroma. The three genotypes in D. graveolens, yellow-fleshed and orange-fleshed, have strong fruity and sweet aromas, while red-fleshed have a strong nutty aroma; however, the D. graveolens perceived an intense alcohol aroma compared to the other wild edible durian genotypes. Durio graveolens was characterized by the highest relative amount of alcohol compounds. Gamero et al. [29] stated that depending on the synergistic effect with other flavour-active compounds, the high amount of alcohol compounds can exhibit floral, fruity, or herbal aromas The panellists determined the intensities of the sulfur aroma of the seven genotypes in descending order: D. oxleyanus, D. kutejensis, D. dulcis, D. graveolens (yellow-fleshed), D. graveolens (red-fleshed), D. graveolens (orange-fleshed), and D. zibethinus (Terung iban). Durio zibethinus (Terung iban) possessed a strong sulfur aroma, similar to common durian cultivars [18,19]; however, it has a weak floral, grassy, and nutty aroma. This is most likely due to D. zibethinus (Terung iban) sensing the most sulfur-containing compounds (Table 4), such as ethanethiol, diethyl disulfide, ethyl 1-methylethyl disulfide, diethyl trisulfide, and 3,5-dimethyl-1,2,4-trithiolane.
3.6. Correlation Analysis between Volatile Organic Compounds (VOCs) and Aroma Profiles
Partial least square (PLS) regression model analysis has been previously used to determine the relationship between the sensory and volatile profiling of durian [18], peach [30], and melon [31]. Thus, in this study, PLS model was performed to correlate the sensory scores with the volatile organic compounds of the wild edible durians that were detected using chromatography. The sensory data set was defined as the y-variable, and the amount of the volatile organic compounds was determined as the x-variables under the hypothesis that the volatile organic compound profile might primarily influence the sensory perception of durian. As can be seen in the PLS loading biplot (Figure 5), the seven genotypes were grouped into four following quadrants.
This result was confirmed with QDA data in which D. graveolens, yellow-fleshed and orange-fleshed, in Quadrant I, grouped as having alcohol, nutty, fruity, and sweet aroma as there is the presence of various volatile organic compounds. The compounds such as 3-methyl-1-butanol, 2-methyl-1-propanethiol strongly correlate to alcohol aroma (0.887 and 0.920, respectively), 2-methyl-3-hexanol and 2,7-dimethyl-4,5-octanediol strongly correlate with fruity aroma (0.789 and 0.779, respectively) and 1,4,7,10,13,16-hexaoxacyclooctadecane strongly correlate with nutty aroma (0.785), where all of these compounds might contribute to the various aroma in D. graveolens, yellow and orange-fleshed. This PLS result grouped D. graveolens (red-fleshed) and D. zibethinus (Terung iban) in Quadrant II because both genotypes had presented of high relative amount of diethyl disulfide (H5), and it was a strongly positive correlate (0.890) (Table 5) with sulfur aroma. Some sulfur-containing compounds, such as ethanethiol, ethyl 1-methylethyl disulfide, diethyl trisulfide and 3,5-dimethyl-1,2,4-trithiolane were correlated strongly to the sulfury aroma, with correlation value between 0.890 to 0.901. Durio kutejensis and Durio oxleyanus grouped together in Quadrant III due to their mild aroma, which was proven in the QDA correlation. Durio dulcis (Quadrant IV) was shown to have a different aroma profile than other genotypes. The aldehyde compounds, 2-methyl-propanal (B1) and 5-hydroxymethylfurfural (B5), which were described as having green and floral odor were strongly correlated (0.759 and 0.852, respectively) with grassy aroma (Table 5). These compounds were probably separating D. dulcis from other genotypes. Butanoic acid, 2-methyl-, ethyl ester (D6), an ester compound, has a high amount in D. dulcis but did not correlate well with a fruity aroma. This is in agreement with the findings by Belgis et al. [16] and Voon et al. [18], where the concentration of butanoic acid, 2-methyl-, ethyl ester did not increase linearly with an increase in the intensity of fruity aroma.
4. Conclusions
A total of 119 volatile organic compounds were identified in the wild edible durians, with ester (20–40%) and alcohol (18–36%) compounds being the most predominant. This is probably the main cause of the distinct aroma patterns in wild durians compared to the well-known cultivars of D. zibethinus. PCA clearly classified the wild durians into different groups. Durio dulcis, D. graveolens (yellow-, and orange-fleshed), D. kutejensis, and D. oxleyanus possessed two to ten-fold higher levels of ester compounds compared to D. zibethinus (Terung iban). Ester compounds are generally linked to pleasant smell and are often responsible for the fruity aroma. Durio zibethinus (Terung iban) possessed a higher relative amount of sulfur-containing compounds, where responsible for the onion-like pungent odor. A higher relative amount of ketone and ether in D. graveolens (red-fleshed) gives the durian a floral, fruity, and sweet odor while D. oxleyanus with higher nitrogen-containing compounds, is characterized by a nutty smell. Based on the QDA analysis, D. kutejensis has the mildest aroma among wild edible durians, with a less intense sulfury, fruity, and sweet aroma. Durio dulcis perceived a stronger sweet and grassy aroma, while D. graveolens had an intense alcohol aroma compared to the other wild edible durian genotypes. The partial least square (PLS) correlation coefficient confirmed the relationship between the aroma and volatile organic compounds of the durian species. This finding is an approach to identifying the potential of these wild edible durians, which will aid in breeding efforts to produce new durian cultivars and improve the sensory quality of the fruit to increase consumer satisfaction.
Author Contributions
G.B.S. was the leading researcher for this project who contributed to the experiment setup, data collection, and interpretation of the results. They have taken the lead in writing the manuscript. S.D.R. conceived the presented idea, provided critical feedback, and helped shape the research, analysis, and manuscript writing. N.S. and S.Y.L. helped supervise the project, provided critical feedback, and helped shape the research, analysis, and manuscript. All authors have read and agreed to the published version of the manuscript.
Funding
This research was funded by the Fundamental Research Grant Scheme (FRGS) awarded by the Ministry of Higher Education Malaysia, grant number FRGS/1/2020/STG03/UPM/02/10.
Data Availability Statement
All data generated or analyzed during this study are included in this published article.
Acknowledgments
The authors are grateful to the Ministry of Higher Education Malaysia for awarding the Fundamental Research Grant Scheme (FRGS), (FRGS/1/2020/STG03/UPM/02/10) and Universiti Putra Malaysia for the facilities and support provided for this project. The authors also thank Sarawak Biodiversity Centre for approval given JKM/SPU/608–8/2/1 Vol.3 to conduct research on Sarawak indigenous durians.
Conflicts of Interest
The authors declare no conflict of interest.
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Figure 1.
Sampling locations for Durio species in Sarawak (Source: Google Earth Pro, 2022).
Figure 2.
The composition of chemical classes in the seven durian genotypes of Sarawak; (a) Durio dulcis, (b) Durio graveolens (yellow–fleshed), (c) Durio graveolens (orange–fleshed), (d) Durio graveolens (red–fleshed), (e) Durio kutejensis, (f) Durio oxleyanus, and (g) Durio zibethinus (Terung iban).
Figure 2.
The composition of chemical classes in the seven durian genotypes of Sarawak; (a) Durio dulcis, (b) Durio graveolens (yellow–fleshed), (c) Durio graveolens (orange–fleshed), (d) Durio graveolens (red–fleshed), (e) Durio kutejensis, (f) Durio oxleyanus, and (g) Durio zibethinus (Terung iban).
Figure 3.
Prinicpal Component Analysis (PCA) biplot of wild edible durians in Sarawak. The code of the volatile organic compounds was referred to in the list of the volatile organic compounds in Table 4.
Figure 3.
Prinicpal Component Analysis (PCA) biplot of wild edible durians in Sarawak. The code of the volatile organic compounds was referred to in the list of the volatile organic compounds in Table 4.
Figure 4.
Spider-web of seven aroma sensory attributes in seven wild edible durians in Sarawak.
Figure 5.
Partial least square (PLS) biplot of seven genotypes of wild edible durians.
Table 1.
GPS coordinate and sampling location description for wild edible Durio species in Sarawak.
| Code | Species | Local Name | Locations | Coordinates | Habitat |
|---|---|---|---|---|---|
| D1 | D. dulcis | Tutong | Tatau, Sarawak | N 2° 45’ 47.88″, E 112° 57’ 43.92″ | Forest |
| D2 | D. graveolens (yellow–fleshed) | Isu kuning | Sibu, Sarawak | N 2° 17’ 16.00″, E 111° 49’ 50.99″ | Forest |
| D3 | D. graveolens (orange–fleshed) | Isu oren | Niah, Sarawak | N 3° 51’ 43.20″, E 113° 42’ 51.48″ | Forest |
| D4 | D. graveolens (red–fleshed) | Isu merah | Baram, Sarawak | N 4° 6’ 43.91″, E 114° 22’ 46.42″ | Forest |
| D5 | D. kutejensis | Nyekak | Bekenu, Sarawak | N 4° 3’ 29.47”, E 113° 50’ 39.09” | Orchard |
| D6 | D. oxleyanus | Daun | Baram, Sarawak | N 4° 6’ 43.92″, E 114° 22’ 49.44″ | Forest |
| D7 | D. zibethinus | Terung iban | Tatau, Sarawak | N 2° 45’ 47.86″, E 112° 57’ 41.90″ | Forest |
Table 2.
Aroma sensory attributes that evaluated in the descriptive analysis.
| Attributes | Description |
|---|---|
| Sweet | Aroma associated with ripened honeydew |
| Fruity | A mixture of aromas associated with fruit, like a banana, melon |
| Sulfury | Aroma associated with rotten egg aroma |
| Alcohol | Aroma associated with fermented rice liquid or alcohol |
| Nutty | The aroma of the nuts |
| Grassy | The aroma of fresh-cut grass |
| Floral | Aroma associated with ripened passion fruit or flower |
Table 3.
Morphological variabilities of seven wild edible durian genotypes from Sarawak.
| Species | D. dulcis | D. graveolens (Yellow-Fleshed) | D. graveolens (Orange-Fleshed) | D. graveolens (Red-Fleshed) | D. kutejensis | D. oxleyanus | D. zibethinus |
|---|---|---|---|---|---|---|---|
 |  |  |  |  |  |  | |
| 10 cm | 6 cm | 6 cm | 6 cm | 6 cm | 8 cm | 10 cm | |
| Fruit shape | Globose to obovoid | Globose to obovoid | Globose to obovoid | Globose to obovoid | Obovate | Globose | Ovoid |
| Base shape | Flat to round | Flat to round | Flat to round | Flat to round | Acute | Convex | Round |
| Pericarp colour (visual) | Red to dark red | Green | Green | Yellow to green | Yellow | Green | Pale green to green |
| Carpel easiness of splitting | Difficult | Difficult | Difficult | Easy | Easy | Difficult | Easy |
| Spine shape | Conical | Conical | Conical | Conical | Pyramidal | Pyramidal with conical and sharp points | Pointed convex |
 |  |  |  |  |  |  | |
| Aril colour (visual) | Pale yellow | Yellow | Orange | Red | Yellow | Pale yellow | Pale yellow |
| Fruit length (cm) | 14.50 ± 2.66 a | 12.10 ± 2.39 b | 11.35 ± 1.53 b | 11.15 ± 1.55 b | 12.78 ± 0.75 ab | 12.05 ± 1.46 b | 12.95 ± 0.60 ab |
| Fruit width (cm) | 15.90 ± 2.81 a | 13.12 ± 1.60 bc | 13.28 ± 1.06 bc | 13.1 5± 1.53 bc | 11.20 ± 0.82 c | 12.75 ± 1.16 bc | 13.70 ± 1.53 ab |
| Fruit weight (g) | 865.1 ± 383.1 a | 559.0 ± 239.0 b | 489.3 ± 104.8 b | 504.0 ± 199.0 b | 469.1 ± 94.5 b | 541.7 ± 115.8 b | 719.6 ± 99.6 ab |
| Thickness of aril (mm) | 5.75 ± 2.19 e | 24.08 ± 3.422 b | 15.96 ± 3.17 cd | 21.27 ± 4.98 bc | 31.18 ± 5.41 a | 12.31 ± 4.78 d | 30.65 ± 3.73 a |
The values are presented as the means ± standard deviation. Different superscript alphabets in the same row indicate differences at p < 0.05 (ANOVA, Tukey’s test).
Table 4.
List of volatile organic compounds (VOCs) and their chemical classes, odorant description, CAS number, and retention time (RT) in seven genotypes of wild edible Durio species in Sarawak obtained using the headspace SPME GC–MS method.
Table 4.
List of volatile organic compounds (VOCs) and their chemical classes, odorant description, CAS number, and retention time (RT) in seven genotypes of wild edible Durio species in Sarawak obtained using the headspace SPME GC–MS method.
| Compounds | Odor Description [27,28] | CAS | RT | Relative Amount in the Headspace | |||||||
|---|---|---|---|---|---|---|---|---|---|---|---|
| D1 | D2 | D3 | D4 | D5 | D6 | D7 | |||||
| Alcohol | |||||||||||
| A1 | Propyl mercaptan | Sulfuraceous | 107–03−9 | 1.51 | 21.14 | ||||||
| A2 | 4-Octanol, 2-[(tert.butyloxycarbonyl) amino] | 1000164–64−5 | 1.62 | 16.91 | |||||||
| A3 | 1-Pentanol, 4-amino- | 927–55−9 | 1.74 | 6.94 | |||||||
| A4 | 4-Pentanol, 2-[(tert.butyloxycarbonyl)amino] | 1000164–64−4 | 1.85 | 3.51 | |||||||
| A5 | Ethanol | Vinous odor | 64–17−5 | 1.98 | 157.26 | 81.66 | 27.63 | 48.57 | |||
| A6 | 2-Hexanol | Fatty, terpenic | 626–93−7 | 2.21 | 21.14 | ||||||
| A7 | 1-Propanol, 2-methyl- | Sweet, musty | 78–83−1 | 2.88 | 181.00 | 368.38 | |||||
| A8 | 1-Butanol, 3-methyl- | Whiskey | 123–51−3 | 3.43 | 458.54 | 553.44 | 553.12 | 52.39 | |||
| A9 | 2-Furanmethanol, tetrahydro-, acetate | Fruity, ethereal | 637–64−9 | 3.47 | 8.59 | ||||||
| A10 | 1-Pentanol | Mild alcohol odor | 71–41−0 | 3.60 | 15.86 | ||||||
| A11 | Ethanol, 2-(vinyloxy)- | 764–48−7 | 3.77 | 9.90 | |||||||
| A12 | 1,2-Propanediol, 3-methoxy- | 623–39−2 | 3.85 | 36.57 | |||||||
| A13 | 1-Hexanol | Fruity, alcohol | 111–27−3 | 3.91 | 116.83 | ||||||
| A14 | 3-Hexanol, 2-methyl- | Flavouring agent | 617–29−8 | 3.99 | 270.50 | 160.50 | |||||
| A15 | 4-Heptanol, 2,6-dimethyl- | Flavouring agent | 108–82−7 | 4.32 | 175.26 | ||||||
| A16 | 2,3-Butanediol | Creamy, buttery | 513–85−9 | 4.45 | 55.34 | 71.93 | 72.61 | ||||
| A17 | 2-(Ethylsulfonyl)ethanol | Meaty flavor | 513–12−2 | 4.45 | 87.87 | ||||||
| A18 | 1-Deoxy-d-altritol | 68832–18−8 | 4.64 | 32.06 | |||||||
| A19 | Ethanol, 2-(1-methylethoxy)- | Mild, ethereal | 1000153–20−8 | 4.69 | 9.01 | ||||||
| A20 | 2-Furanmethanol | Warm, oily, burnt | 5405–41−4 | 4.75 | 143.14 | 78.77 | 92.30 | 75.61 | 137.94 | 27.59 | |
| A21 | 4,5-Octanediol, 2,7-dimethyl- | Floral | 1000153–20−8 | 4.94 | 61.16 | 32.52 | |||||
| A22 | 2-Propanol, 1-(1-methylethoxy)- | 3944–36−3 | 5.35 | 9.51 | |||||||
| A23 | Phenylethyl Alcohol | Rose-like floral | 60–12−8 | 5.37 | 40.20 | 22.12 | |||||
| A24 | Trimethylsilyloxy)ethoxy]ethoxy]ethoxy]ethoxy]ethoxy]ethoxy]ethanol | 1000131–70−7 | 5.39 | 21.42 | |||||||
| A25 | 4-Amino−1-butanol | 13325–10−5 | 5.49 | 21.09 | |||||||
| A26 | (3-Methyl-oxiran−2-yl)-methanol | 1000194–22−9 | 5.94 | 43.47 | 17.35 | ||||||
| A27 | 1,6-Dideoxy-l-mannitol | 68832–20−2 | 6.06 | 10.15 | |||||||
| A28 | 2-Hexadecanol | 14852–31−4 | 6.21 | 32.04 | 11.53 | ||||||
| A29 | 2-Eicosanol | 4340–76−5 | 6.42 | 9.24 | |||||||
| A30 | Ethanol, 2-[2-(2-butoxyethoxy)ethoxy]- | Mild odor | 143–22−6 | 6.52 | 29.57 | ||||||
| A31 | 2-Dodecanol | Flavouring agent | 10203–28−8 | 7.12 | 6.25 | ||||||
| A32 | Ethanol, 2-bromo- | Sweet burning | 540–51−2 | 7.37 | 1.67 | ||||||
| Total | 543.03 | 1013.46 | 1079.61 | 1099.47 | 514.83 | 217.83 | 130.87 | ||||
| Aldehyde | |||||||||||
| B1 | Propanal, 2-methyl- | Pungent, floral | 78–84−2 | 1.44 | 68.66 | 73.03 | |||||
| B2 | Furan−3-carboxaldehyde, 2-methoxy- | 1000132–11−1 | 5.14 | 30.56 | |||||||
| B3 | DL-Arabinose | 29493–06−9 | 5.19 | 13.46 | |||||||
| B4 | 3-(1-Ethoxyethoxy)-butyraldehyde | 116616–30−9 | 5.28 | 9.68 | |||||||
| B5 | 5-Hydroxymethylfurfural | Chamomile | 67–47−0 | 6.79 | 224.71 | 144.09 | 109.13 | 26.88 | 53.74 | 65.38 | 31.79 |
| Total | 323.93 | 144.09 | 191.84 | 40.34 | 53.74 | 65.38 | 31.79 | ||||
| Amine | |||||||||||
| C1 | 1-Butanamine, N-methyl- | Ammonia-like | 110–68−9 | 1.34 | 7.43 | ||||||
| C2 | 3-Methoxyamphetamine | 17862–85−0 | 1.37 | 12.09 | |||||||
| C3 | Ethylamine | Fishy | 75–04−7 | 5.93 | 37.94 | ||||||
| C4 | Dimethylamine | Fishy | 124–40−3 | 7.21 | 8.33 | ||||||
| Total | 0.00 | 0.00 | 12.09 | 0.00 | 15.76 | 37.94 | 0.00 | ||||
| Ester | |||||||||||
| D1 | Propanoic acid, 2-methyl-, methyl ester | Fruity (apple) | 144–62−7 | 1.88 | 37.65 | ||||||
| D2 | Propanoic acid, 2-methyl-, ethyl ester | Fruity (Citrus) | 97–62−1 | 2.17 | 271.07 | 663.51 | 531.72 | 80.86 | |||
| D3 | (R)-(-)-Methyl 3-hydroxybutyrate | 3976–69−0 | 2.28 | 6.94 | |||||||
| D4 | Butanoic acid, ethyl ester | Fruity (pineapple) | 109–21−7 | 2.54 | 33.04 | ||||||
| D5 | Butanoic acid, 3-methyl-, ethyl ester | Strong, Fruity | 108–64−5 | 2.65 | 13.63 | ||||||
| D6 | Butanoic acid, 2-methyl-, ethyl ester | Fruity, wine | 7452–79−1 | 2.66 | 1234.71 | 43.53 | 78.80 | 20.23 | 163.64 | 317.99 | |
| D7 | Butanoic acid, butyl ester | Fruity (pear) | 109–21−7 | 2.79 | 2898.95 | ||||||
| D8 | Propanoic acid, 2-methyl-, butyl ester | Strong, fresh | 2050–01−3 | 2.82 | 247.48 | ||||||
| D9 | Propanoic acid, 2-methyl-, 2-methylpropyl | Sweet, estry | 97–85−8 | 2.83 | 37.29 | ||||||
| D10 | Butanoic acid, heptyl ester | Chamomile-like | 5870–93−9 | 2.85 | 3656.76 | ||||||
| D11 | Butanoic acid, 2-methyl-, propyl ester | Fruity, sweet | 37064–20−3 | 3.04 | 50.43 | 5.50 | 43.14 | 121.35 | |||
| D12 | Butanoic acid, 2-methylpropyl ester | Fruity (melon) | 2445–67−2 | 3.14 | 45.71 | ||||||
| D13 | 2-Butenoic acid, ethyl ester, (E)- | Pungent, sharp | 623–70−1 | 3.16 | 64.09 | ||||||
| D15 | Propanoic acid, 2-methyl-, 3-methylbutyl ester | Sweet, Fruity | 2050–01−3 | 3.24 | 209.08 | 315.87 | 81.95 | ||||
| D16 | 2-Butenoic acid, 2-methyl-, ethyl ester | – | 55514–48−2 | 3.40 | 329.89 | ||||||
| D17 | Heptanoic acid, methyl ester | Sweet, Berry | 108–82−7 | 3.63 | 18.91 | ||||||
| D18 | Hexanoic acid, propyl ester | Ether-like | 626–77−7 | 3.70 | 3.10 | ||||||
| D19 | Butanoic acid, 2-hydroxy−2-methyl- | 32793–34−3 | 3.76 | 68.28 | |||||||
| D20 | Hexanoic acid, 2-methylpropyl ester | Cocoa-like | 105–79−3 | 3.84 | 105.49 | 97.92 | |||||
| D21 | Butanedioic acid, 2,3-bis(acetyloxy)- | 51591–38−9 | 3.97 | 47.91 | |||||||
| D22 | Octanoic acid, ethyl ester | Cocoa odor | 106–32−1 | 4.11 | 37.20 | 16.73 | |||||
| D23 | Hexanoic acid, ethyl ester | Sweet, fruity | 123–66−0 | 4.14 | 13.06 | ||||||
| D24 | 2,4-Hexadienoic acid, methyl ester, (E,E)- | Sweet, fruity | 689–89−4 | 4.15 | 9.98 | ||||||
| D25 | Pentanoic acid, 2-hydroxy−4-methyl-, ester | Fruity, musty | 40348–72−9 | 4.32 | 111.55 | ||||||
| D26 | n-Caprylic acid isobutyl ester | Fruity, floral | 5461–06−3 | 4.56 | 65.50 | 23.68 | |||||
| D27 | Arsenous acid, tris(trimethylsilyl) ester | 116616–30−9 | 4.99 | 12.54 | |||||||
| D28 | .beta.-Alanine, trimethylsilyl ester | 5269–40−9 | 4.99 | 6.22 | |||||||
| D29 | Butanoic acid, 3-hydroxy-, ethyl ester | Grape odor | 5405–41−4 | 5.18 | 5.83 | ||||||
| D30 | 10-Bromodecanoic acid, ethyl ester | 55099–31−5 | 5.25 | 21.80 | |||||||
| D31 | Acetic acid, hydroxy-, ethyl ester | 623–50−7 | 5.27 | 10.51 | |||||||
| D32 | Pentanoic acid, 1-methylethyl ester | Fruity | 18362–97−5 | 5.27 | 13.68 | ||||||
| D33 | Methoxyacetic acid, 2-pentadecyl ester | 1000282–05−1 | 5.40 | 17.39 | |||||||
| D34 | Succinic acid, (4-methoxyphenyl) ester | 029493–06−9 | 5.55 | 46.98 | |||||||
| D35 | alpha.-Aminooxy-propionic acid, ethyl ester | 5766–86−9 | 5.62 | 13.40 | 9.23 | ||||||
| D36 | N-Hydroxycarbamic acid | 28564–83−2 | 5.76 | 40.78 | |||||||
| D37 | Propanoic acid, ethyl ester | Odor reminiscent | 105–37−3 | 6.35 | 26.37 | 40.05 | 41.91 | 23.87 | |||
| Total | 2147.34 | 4912.20 | 4022.20 | 551.15 | 73.99 | 384.79 | 463.01 | ||||
| Ether | |||||||||||
| E1 | Ethylene oxide | Ethereal | 75–21−8 | 1.20 | 43.97 | ||||||
| E2 | Ethene, ethoxy- | Ethereal odor | 109–92−2 | 1.46 | 26.20 | ||||||
| E3 | Pentane, 1-methoxy- | 97–62−1 | 1.93 | 35.01 | |||||||
| E4 | L(-)-Fucose, tetramethyl ether | 1000332–75−0 | 2.40 | 36.98 | |||||||
| E5 | Octaethylene glycol monododecyl ether | 1000214–51−8 | 5.30 | 17.29 | |||||||
| E6 | Oxirane, (propoxymethyl)- | 3126–95−2 | 5.93 | 25.26 | |||||||
| E7 | Methyl 6,8-dodecadienyl ether | 1000130–99−9 | 6.41 | 22.92 | |||||||
| E8 | 1,4,7,10,13,16-Hexaoxacyclooctadecane | 1000194–22−9 | 6.97 | 2.50 | 21.30 | 51.06 | 63.17 | 6.62 | 8.58 | 3.04 | |
| E9 | 15-Crown−5 | 33100–27−5 | 7.21 | 10.08 | 3.74 | ||||||
| E10 | 2,3-Epoxybutane | 3266–23−7 | 7.22 | 5.34 | |||||||
| Total | 98.68 | 65.27 | 51.06 | 115.47 | 31.88 | 13.92 | 6.78 | ||||
| Ketone | |||||||||||
| F1 | 2-Acetyl−3-methylpyrazine | Nutty odor | 23787–80−6 | 3.61 | 9.88 | ||||||
| F2 | 5-Hepten−2-one, 6-methyl- | Fruity | 5461–06−3 | 3.85 | 160.02 | ||||||
| F3 | Acetoin | Bland, woody, | 513–86−0 | 3.87 | 60.44 | ||||||
| F4 | 2-Cyclohexen−1-one, 2-methyl- | 1121–18−2 | 4.67 | 11.37 | |||||||
| F5 | 3-Octen−2-one, 4-methoxy- | Earthy, spicy, | 24985–52−2 | 4.82 | 100.92 | ||||||
| F6 | 2-Cyclopenten−1-one, 2-hydroxy- | Caramellic type | 10493–98−8 | 5.06 | 14.64 | ||||||
| F7 | 2H-Imidazol−2-one, 1,3-dihydro−4-methyl- | 60–12−8 | 5.08 | 22.31 | |||||||
| F8 | 3,4-Dihydroxy−5-methyl-dihydrofuran−2-one | 1000193–83−1 | 5.17 | 8.46 | |||||||
| F9 | 2-Propanone, 1-(1,3-dioxolan−2-yl)- | 767–04−4 | 5.27 | 26.11 | |||||||
| F10 | 4H-Pyran−4-one, 3,5-dimethyl- | 19083–61−5 | 5.55 | 44.83 | |||||||
| F11 | 2-Hydroxy−3-pentanone | Flavouring agent | 5704–20−1 | 5.94 | 69.57 | ||||||
| F12 | 4H-Pyran−4-one, 3,5-dihydroxy−6-methyl- | 28564–83−2 | 6.14 | 125.38 | 87.64 | 54.20 | 43.78 | 27.41 | 43.78 | 17.65 | |
| F13 | 6-Propyltetrahydro−2H-thiopyran−2-one | 201991–53−9 | 6.68 | 5.44 | |||||||
| Total | 181.580 | 284.24 | 54.20 | 226.11 | 50.51 | 119.54 | 17.65 | ||||
| Nitrogen-containing compound | |||||||||||
| G1 | Pyrazine, 2-ethyl−5-methyl- | Nutty odor | 13360–64−0 | 4.08 | 9.12 | ||||||
| G2 | Pyrazine, 3-ethyl−2,5-dimethyl- | 13360–65−1 | 4.24 | 487.27 | |||||||
| G3 | 1H-Imidazole, 2-ethyl- | 20185–22−2 | 4.33 | 9.97 | |||||||
| G4 | Imidazole, 1,4,5-trimethyl- | 1000222–86−6 | 4.66 | 14.99 | |||||||
| G5 | Oxime-, methoxy-phenyl- | Fishy odor | 13360–65−1 | 4.88 | 7.60 | 4.46 | |||||
| G6 | 3-Methyl−3-isopropyldiaziridine | 24476–95−7 | 5.74 | 34.25 | |||||||
| G7 | Tetramethylhydrazine | Ammonia-like | 6415–12−9 | 5.74 | 33.71 | ||||||
| G8 | Isoxazolidine, 4-ethyl−2,5-dimethyl-, cis- | Burnt-type odor | 56701–01−0 | 5.74 | 15.53 | ||||||
| Total | 0.00 | 0.00 | 0.00 | 0.00 | 34.25 | 552.69 | 29.96 | ||||
| Sulfur-containing compound | |||||||||||
| H1 | Acetaldehyde | Ethereal | 75–07−0 | 1.18 | 52.51 | 46.43 | 29.20 | ||||
| H2 | Ethanethiol | Overpowering | 75–08−1 | 1.25 | 24.74 | ||||||
| H3 | 1-Propanethiol, 2-methyl- | Sulfurous | 513–44−0 | 1.51 | 89.50 | 91.30 | 91.30 | ||||
| H4 | Propanethioic acid, 2-methyl-, S-ethyl ester | 72437–68−4 | 3.12 | 36.72 | |||||||
| H5 | Diethyl disulfide | Roasted onion | 110–81−6 | 3.31 | 53.74 | 19.41 | 258.84 | ||||
| H6 | Disulfide, ethyl 1-methylethyl | 53966–36−2 | 3.67 | 47.44 | |||||||
| H7 | Methyl pentyl disulfide | Sulfurous | 72437–68−4 | 3.72 | 4.47 | ||||||
| H8 | Trisulfide, diethyl | Alliaceous, | 3600–24−6 | 4.45 | 42.25 | ||||||
| H9 | 1,2,4-Trithiolane, 3,5-dimethyl- | Sulfurous | 23654–92−4 | 4.76 | 37.51 | ||||||
| H10 | Divinyl sulfide | Evil smelling | 627–51−0 | 6.35 | 34.22 | ||||||
| Total | 52.51 | 89.50 | 95.77 | 228.19 | 63.42 | 19.41 | 410.78 | ||||
Table 5.
Correlation coefficients between the volatile organic compounds detected from the seven genotypes of wild durians and its sensory description.
Table 5.
Correlation coefficients between the volatile organic compounds detected from the seven genotypes of wild durians and its sensory description.
| Compounds | Sweet | Fruity | Sulfur | Alcohol | Nutty | Grassy | Floral |
|---|---|---|---|---|---|---|---|
| Propyl mercaptan | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| 1−Butanol, 3−methyl− | 0.387 | 0.573 | −0.010 | 0.887 | 0.509 | −0.134 | 0.527 |
| Ethanol, 2−(vinyloxy)− | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| 1,2−Propanediol, 3−methoxy− | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| 3−Hexanol, 2−methyl− | 0.447 | 0.799 | −0.043 | 0.720 | 0.217 | 0.230 | 0.623 |
| 4,5−Octanediol, 2,7−dimethyl− | 0.440 | 0.789 | −0.050 | 0.708 | 0.240 | 0.215 | 0.612 |
| 2−Propanol, 1−(1−methylethoxy)− | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| Phenylethyl Alcohol | 0.442 | 0.792 | −0.048 | 0.712 | 0.233 | 0.220 | 0.616 |
| Propanal, 2-methyl− | 0.678 | 0.537 | 0.005 | 0.288 | −0.120 | 0.759 | 0.650 |
| 5−Hydroxymethylfurfural | 0.746 | 0.628 | −0.255 | 0.251 | 0.233 | 0.852 | 0.744 |
| Propanoic acid, 2-methyl−, ethyl ester | 0.663 | 0.905 | −0.112 | 0.728 | 0.209 | 0.532 | 0.778 |
| Propanoic acid, 2−methyl−, 3−methylbutyl ester | 0.474 | 0.762 | 0.036 | 0.836 | 0.127 | 0.213 | 0.637 |
| Hexanoic acid, 2−methylpropyl ester | 0.467 | 0.813 | −0.006 | 0.752 | 0.102 | 0.291 | 0.650 |
| Acetic acid, hydroxy−, ethyl ester | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| .alpha.−Aminooxy-propionic, ethyl ester | −0.861 | −0.787 | −0.581 | −0.616 | −0.326 | 0.065 | −0.409 |
| Propanoic acid, ethyl ester | 0.612 | 0.796 | −0.271 | 0.665 | 0.132 | 0.686 | 0.645 |
| 1,4,7,10,13,16−Hexaoxacyclooctadecane | 0.041 | −0.018 | −0.095 | 0.467 | 0.785 | −0.555 | 0.013 |
| 4H−Pyran−4-one, 2,3−dihydro−3,5–6-methy− | 0.791 | 0.630 | −0.313 | 0.372 | 0.497 | 0.728 | 0.736 |
| Isoxazolidine, 4−ethyl−2,5−dimethyl−, cis− | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| Ethanethiol | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| 1−Propanethiol, 2−methyl− | 0.440 | 0.639 | 0.002 | 0.920 | 0.542 | −0.123 | 0.542 |
| Diethyl disulfide | −0.151 | −0.199 | 0.890 | −0.393 | −0.439 | −0.690 | −0.633 |
| Disulfide, ethyl 1−methylethyl | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| Trisulfide, diethyl | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
| 1,2,4−Trithiolane, 3,5−dimethyl− | −0.121 | −0.137 | 0.901 | −0.442 | −0.560 | −0.559 | −0.560 |
Significant correlations at the p < 0.05 level are marked in bold.
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Sujang, G.B.; Ramaiya, S.D.; Saupi, N.; Lee, S.Y. Profiling of Volatile Organic Compounds (VOCs) of Wild Edible Durians from Sarawak, Borneo Associated with Its Aroma Properties. Horticulturae 2023, 9, 257. https://0-doi-org.brum.beds.ac.uk/10.3390/horticulturae9020257
AMA Style
Sujang GB, Ramaiya SD, Saupi N, Lee SY. Profiling of Volatile Organic Compounds (VOCs) of Wild Edible Durians from Sarawak, Borneo Associated with Its Aroma Properties. Horticulturae. 2023; 9(2):257. https://0-doi-org.brum.beds.ac.uk/10.3390/horticulturae9020257
Chicago/Turabian StyleSujang, Gerevieve Bangi, Shiamala Devi Ramaiya, Noorasmah Saupi, and Shiou Yih Lee. 2023. "Profiling of Volatile Organic Compounds (VOCs) of Wild Edible Durians from Sarawak, Borneo Associated with Its Aroma Properties" Horticulturae 9, no. 2: 257. https://0-doi-org.brum.beds.ac.uk/10.3390/horticulturae9020257
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