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Physicochemical difference of coffee beans with different species, production areas and roasting degrees

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  • In recent decades, the demand for coffee has seen a continuous increase, and the aroma and flavor of coffee has been widely studied. The current research chose coffee beans of two species (Coffea arabica and C. canephora) from five production areas (Brazil, India, Indonesia, Uganda and Vietnam) with four different roasting degrees (medium light, medium, medium dark and dark), to investigate the difference on physicochemical properties. The results showed that Arabica coffee beans had higher concentrations of fat and organic acids, and total amount of volatile compounds, whereas Robusta beans had higher concentrations of protein. With the increase of roasting degree, the concentrations of protein, fat, organic acids, and the total amount of volatile compounds of coffee beans increased, while the concentrations of chlorogenic acid compounds decreased. The discriminant analysis indicated that the tested coffee beans could be clearly discriminated by species and roasting degrees, but not by production area. The results of this research conclude the physicochemical difference of Arabica and Robusta beans with different roasting degrees. The results can provide a theoretical basis for coffee bean selection for the relevant industries.
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  • Supplemental Table1 Amount of Volatile Compounds of Each Coffee Bean.
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  • Cite this article

    Liu X, Fei Y, Wang W, Lei S, Cheng C, et al. 2022. Physicochemical difference of coffee beans with different species, production areas and roasting degrees. Beverage Plant Research 2: 7 doi: 10.48130/BPR-2022-0007
    Liu X, Fei Y, Wang W, Lei S, Cheng C, et al. 2022. Physicochemical difference of coffee beans with different species, production areas and roasting degrees. Beverage Plant Research 2: 7 doi: 10.48130/BPR-2022-0007

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ARTICLE   Open Access    

Physicochemical difference of coffee beans with different species, production areas and roasting degrees

Beverage Plant Research  2 Article number: 7  (2022)  |  Cite this article

Abstract: In recent decades, the demand for coffee has seen a continuous increase, and the aroma and flavor of coffee has been widely studied. The current research chose coffee beans of two species (Coffea arabica and C. canephora) from five production areas (Brazil, India, Indonesia, Uganda and Vietnam) with four different roasting degrees (medium light, medium, medium dark and dark), to investigate the difference on physicochemical properties. The results showed that Arabica coffee beans had higher concentrations of fat and organic acids, and total amount of volatile compounds, whereas Robusta beans had higher concentrations of protein. With the increase of roasting degree, the concentrations of protein, fat, organic acids, and the total amount of volatile compounds of coffee beans increased, while the concentrations of chlorogenic acid compounds decreased. The discriminant analysis indicated that the tested coffee beans could be clearly discriminated by species and roasting degrees, but not by production area. The results of this research conclude the physicochemical difference of Arabica and Robusta beans with different roasting degrees. The results can provide a theoretical basis for coffee bean selection for the relevant industries.

    • In recent decades, the demand for coffee has been continuously increasing, and the global consumption increased by 1%−2% every year[1]. According to the statistics of the International Coffee Organization, the annual market value of coffee is about 200 billion US dollars, and it is expected that future consumption will continue to drive the demand for coffee[2]. Coffee is a tropical plant, belonging to Rubiaceae. There are 124 species of coffee in the genus Coffea[3], but only two species − Arabica (C. arabica) and Robusta (C. canephora) are commercially traded in the international market. Arabica coffee grows well in a cool climate and at high altitude (1,000−2,100 m) while Robusta grows better in a hot and humid climate at lower altitude (100−1,000 m)[4]. At present, the main coffee production areas are located between 25° north latitude and 30° south latitude, among which Brazil, Indonesia, India, Uganda, and Vietnam are the main production areas worldwide[5].

      Recently, many studies have been carried out on how the quality of coffee beans are affected by species, geographical origin, postharvest processing and production processing[4,6], Luca et al.[7] characterized the effects of different roasting conditions on coffee of different geographical origin by high performance liquid chromatograph (HPLC) with photo-diode array detector, near infrared spectrum instrument (NIRS) and stoichiometry, and concluded that different roasting conditions and geographical origin influenced the properties of roasted coffee beans. And the aroma and flavor of coffee beans has been widely studied, and many conclusions obtained. Kučera et al.[8] analyzed espresso coffee with different roasting degrees (light, medium, medium dark and dark) by ultra-performance liquid chromatography-tandem mass spectrometry. The obtained raw data were analyzed using multivariate statistics to assess the difference between each degree of baking. Cui et al.[9] found that coffee made from the coffee beans of two species exhibited a different, special flavor, as Arabica beans exhibited a 'baked' flavor and Robusta beans exhibited a 'sweet' flavor. The sensory properties, especially the flavor compounds of coffee beans are obviously influenced by production area[5]. In addition, roasting speed and roasting degree also have a significant effect on the aroma components of coffee beans[1,10].

      As well as sensory properties, physicochemical properties of roasted coffee beans are also affected during the production procedure[11]. However, little research has focussed on the physicochemical properties, and at the same time excluded the influence of species, production area and roasting degree. Furthermore, most recent research has focused on the coffee beverage rather than coffee beans. This research chose two species of coffee beans (Arabica and Robusta beans) from five production areas (Brazil, India, Indonesia, Uganda and Vietnam), and roasted them to four different degrees (medium light, medium, medium dark and dark), to investigate the difference on physicochemical properties, such as the concentrations of protein, fat, organic acids, chlorogenic acid compounds (CACs) and the composition of volatile compounds (VCs). The results of this research can provide a theoretical basis for coffee bean selection for the relevant industry.

    • Arabica and Robusta beans produced in five areas were used, and the details are shown in Table 1. Sulfuric acid, hydrochloric acid and sodium hydroxide were analytical pure grade and from Wuxi Zhanwang Chemical Reagent Co., Ltd (Wuxi, China). Acetonitrile and methanol were chromatographically pure grade and from TEDIA Co., Ltd, USA. The water used in all experiments was ultrapure water.

      Table 1.  Dat for 40 coffee beans used in the study.

      Production area/regionSpeciesRoasting degree
      Medium lightMediumMedium darkDark
      Brazil/Espirito SantoArabica
      Robusta
      India/KarnatakaArabica
      Robusta
      Indonesia/SumatraArabica
      Robusta
      Uganda/ElgonArabica
      Robusta
      Vietnam/Lam DongArabica
      Robusta
    • The coffee bean were reasted with 7 grade fire to four roasting degrees (medium light, medium, medium dark and dark) using a roaster (Tino Probat Inc., Germany), then ground to 0.9 mm powder after 24 h storage. The pictures of the forty samples are shown in Table 1.

    • The experiments were carried out in accordance with the method in GB 5009.5—2016 and GB 5009.6—2016, and using Automatic Kieldahl apparatus and a digestion furnace (Hanon Advanced Technology Group Co., Ltd, China).

    • Sample preparation: For exact details please refer to the operation procedure in GB 5009.157—2016. The samples were weighed to 1−2 g in a 50 mL volumetric flask. Then, 30 mL 0.1% phosphoric acid solution was added, followed by ultrasonic treatment for 20 min. Next, 0.1% phosphoric acid solution was added to the volume scale. The flask is then shaken and filtered using a 0.22 μm organic membrane. Samples were then stored at 4 °C in the dark.

      HPLC with an ultraviolet detector (1260, Agilent Technologies Co., Ltd) and a chromatographic column (CAPCELL PAK C18 MG II, 4.6 mm × 250 mm, 5 μm, OSAKA SODA CO., Ltd) was used to determine the acid concentrations, and the determined parameters are shown in Table 1.

    • Sample preparation: Please refer to the operation procedure in Hu et al.'s research[12]. Samples of 1−2 g were weighed in a 50 mL brown volumetric flask. Then, 30 mL methanol-0.1% phosphoric acid (50:50, V/V) solution, was added followed by ultrasonic treatment for 20 min. Methanol-0.1% phosphoric acid (50:50, V/V) solution was then added to the volume scale. The mixture was shaken and then filtered using a 0.22 μm organic membrane. Samples were stored at 4 °C in the dark.

      HPLC was used to determine the CACs concentration, and the determined parameters are shown in Table 2.

      Table 2.  Chromatographic parameters for organic acid and CACs determination.

      ParametersOrganic acidsCACs
      Speed0.3 mL/min1.0 mL/min
      Column temperature40 °C30 °C
      Wavelength210 nm327 nm
      Moving PhaseMethanol (A)-0.1% phosphoric acid solution (B)
      Elution program0.00~20.00 min:
      10%A-90%B
      0.00~20.00 min:
      20%A-80%B
      20.01~25.00 min: 100%A20.01~45.00 min:
      35%A-65%B
      25.01~35.00 min: 10%A-90%B45.01~55.00 min:
      40%A-60%B
      55.01~60.00 min:
      20%A-80%B
    • Firstly, 0.3 g of sample was weighed in a 20 mL headspace sampler, the samples were then analysed by Ultra-fast E-nose (Heracles NEO, Alpha MOS, France)[13], and the parameters are shown in Table 3.

      Table 3.  E-nose parameters for VCs determination.

      ParametersValue
      Incubation temperature60 °C
      Incubation duration30 min
      Injection volume5000 μL
      Injection speed125 μL/s
      Injector temperature200 °C
      Injection time45 s
      Trapping temperature40 °C
      Trapping duration50 s
      Split10 mL/min
      Final temperature250 °C
      Initial temperature50 °C (20 s)
      Temperature program1 °C/s−80 °C (20 s)
      3 °C/s−250 °C (40 s)
      Acquisition duration167 s
      Fid temperature260 °C
      FID gain12
    • Experimental samples were measured three times for each experiment. Data was processed by ExcelTM and Minitab19. One-way analysis of variance (ANOVA) and statistical difference (Fisher Test) was performed at p < 0.05 using Minitab19. Principal Components Analysis (PCA) was performed by Origin 2017. Graphs were made by Origin 2017 and Photoshop CS5.

    • Protein and fat are important components of coffee beans, fats especially play an important role in the sensory attribute of coffee[14]. In addition, protein and fat are also important substances in the Maillard reaction during coffee roasting, which can contribute to the formation of pleasant flavor and color of roasted coffee beans. The results of protein and fat determination are shown in Table 4 and Fig. 1. The protein concentration of Arabica beans with different roasting degrees from all production areas was significantly lower than that of Robusta beans, as the average protein concentration of Arabica beans was about 14.3 g/100 g while that of Robusta beans was about 18.5 g/100 g. Thus, Robusta beans from Brazil, India, Indonesia, Uganda and Vietnam may have more protein than Arabica beans. With the increase of roasting degrees, it is obvious that the protein concentration of Arabica and Robusta beans from five production areas increased. It may also be closely related to the decrease in moisture content. Separating the samples into two groups according to species, a one-way ANOVA was performed at p < 0.05 using Minitab19 for each group. Arabica beans from Brazil and India, and Robusta beans from India and Vietnam had higher protein concentration, while both Arabica and Robusta beans from Indonesia and Uganda had lower protein concentration. Thus, production area may also have a significant influence on the protein concentration of coffee beans, which needs further investigation.

      Table 4.  Protein and fat concentration of each coffee bean (g/100 g).

      SampleProteinFat
      Brazil-A-114.85 ± 0.07jkl6.3 ± 0.28cdefghijk
      Brazil-A-215 ± 0.14ijk5.85 ± 0.49fghijklm
      Brazil-A-315.25 ± 0.07ij6.7 ± 0.14bcdefghi
      Brazil-A-415.75 ± 0.07i7.95 ± 0.49b
      India-A-114.6 ± 0.14jklm5.15 ± 0.49jklmno
      India-A-214.7 ± 0.42jklm5.6 ± 0.42hijklmn
      India-A-314.6 ± 0.28jklm5.6 ± 0.28hijklmn
      India-A-415.05 ± 0.07ijk7.15 ± 0.07bcdefg
      Indonesia-A-113.35 ± 0.07op4.5 ± 0.57mno
      Indonesia-A-213.6 ± 0nop6.2 ± 0.14defghijkl
      Indonesia-A-314.15 ± 0.21lmn6.8 ± 0.42bcdefgh
      Indonesia-A-414.5 ± 0.14jklm7.6 ± 0.14bcd
      Uganda-A-112.55 ± 0.07q5.3 ± 0.57ijklmno
      Uganda-A-212.85 ± 0.07pq6.75 ± 0.92bcdefghi
      Uganda-A-313.1 ± 0.14pq7.95 ± 0.64b
      Uganda-A-413.15 ± 0.07pq10.05 ± 0.35a
      Vietnam-A-114.07 ± 0.21mno6.35 ± 0.52cdefghijk
      Vietnam-A-214.45 ± 0.25klm7.36 ± 0.36bcde
      Vietnam-A-314.69 ± 0.13jklm7.74 ± 0.06bc
      Vietnam-A-414.85 ± 0.07jkl9.46 ± 0.35a
      Brazil-R-117.78 ± 0.3efg4.07 ± 0.3o
      Brazil-R-218.36 ± 0.19def5 ± 0.21jklmno
      Brazil-R-318.8 ± 0.15cd4.87 ± 0.33klmno
      Brazil-R-418.93 ± 0.05bcd5.84 ± 0.21fghijklm
      India-R-119.04 ± 0.08bcd4.85 ± 0.02lmno
      India-R-219.52 ± 0.02abc5.3 ± 0.24ijklmno
      India-R-319.66 ± 0.01ab5.92 ± 0.07efghijklm
      India-R-419.86 ± 0.1a6.19 ± 0.25defghijkl
      Indonesia-R-117.02 ± 0.12h4.33 ± 0.16no
      Indonesia-R-217.34 ± 0.37gh5.72 ± 0.33ghijklmn
      Indonesia-R-317.57 ± 0.19gh5.99 ± 0.21efghijklm
      Indonesia-R-418.37 ± 14def5.99 ± 7.1efghijklm
      Uganda-R-117.44 ± 0.09gh6.15 ± 0.17defghijkl
      Uganda-R-217.68 ± 0.03fgh5.49 ± 0.3hijklmno
      Uganda-R-317.82 ± 0.35efg6.45 ± 0.47cdefghij
      Uganda-R-418.48 ± 0.17de6.39 ± 0.01cdefghij
      Vietnam-R-118.47 ± 0.17de5.52 ± 0.28hijklmno
      Vietnam-R-219.39 ± 0.07abc5.57 ± 0.35hijklmn
      Vietnam-R-319.45 ± 0.24abc6.02 ± 0.14efghijkl
      Vietnam-R-419.94 ± 0.16a7.32 ± 0.09bcdef
      *A: Arabica bean; R: Robusta bean
      1: medium light; 2: medium; 3: medium dark; 4: dark
      Letter code: samples with the same letter code are not significantly different (p < 0.05)

      Figure 1.  Protein and fat concentration of coffee beans (g/100 g). (a) & (b), protein concentration; (c) & (d), fat concentration. Blue represents Arabica beans, orange represents Robusta beans. 1, medium light; 2, medium; 3, medium dark; 4, dark.

      The fat concentration of coffee beans was generally positively correlated to the roasting degree, which was also closely associated with the decrease of moisture content. And, fat concentration of Arabica beans was obviously higher than that of Robusta beans. Thus, roasting degree and species may be significant factors that affect the fat concentration of coffee beans. According to Fig. 1d, there was no significant difference among fat concentration of coffee beans from each production area. Thus, production area might not influence the fat concentration of coffee beans.

    • During the roasting of coffee beans, organic acids are produced while CACs are broken down. Similar to fat and protein, organic acids are also important compounds in the sensory properties of coffee. As they determine the pH value, which is related to the acidity of coffee[13]. The results of organic acids and CACs are shown in Table 5. One-way ANOVA was performed at p < 0.05 using Minitab19 in each species of coffee beans, and the results are shown in Fig. 2.

      Table 5.  Organic acids and CACs concentration of each coffee bean (g/100 g).

      SampleOrganic acidsChlorogenic acids compounds
      Tartaric
      acid
      Malic
      acid
      Citric
      acid
      Succinic
      acid
      Fumaric
      acid
      TotalNeochlorogenic
      acid
      Chlorogenic
      acid
      Cryptochlorogenic
      acid
      Isochlorogenic
      acid A
      Isochlorogenic
      acid B
      Isochlorogenic
      acid C
      Total
      Brazil-A-13.48 ± 0.240.46 ± 0.150.44 ± 0.061.37 ± 0.270 ± 05.75 ± 0.71ghijklmn0.45 ± 0.020.97 ± 0.080.58 ± 0.070.03 ± 0.010.06 ± 0.020.06 ± 0.012.16 ± 0.2de
      Brazil-A-23.44 ± 0.230.48 ± 0.110.64 ± 0.062.13 ± 0.280 ± 06.67 ± 0.21cdefg0.33 ± 00.67 ± 0.020.38 ± 0.020.02 ± 00.03 ± 00.03 ± 01.45 ± 0.01fghi
      Brazil-A-33.97 ± 0.130.53 ± 0.060.69 ± 0.062.49 ± 0.290 ± 07.67 ± 0.04bcd0.22 ± 00.41 ± 0.010.28 ± 0.020 ± 00.02 ± 0.010.02 ± 00.94 ± 0.04jkl
      Brazil-A-44.18 ± 0.230.64 ± 0.051.04 ± 0.071.94 ± 0.110 ± 07.8 ± 0.36bc0.13 ± 00.22 ± 0.010.15 ± 0.010 ± 00 ± 00 ± 00.5 ± 0.02nop
      India-A-12.61 ± 0.250.52 ± 0.040.49 ± 0.041.59 ± 0.050 ± 05.2 ± 0.12hijklmnop0.71 ± 0.11.42 ± 0.040.85 ± 0.070.05 ± 0.010.08 ± 0.010.08 ± 0.013.19 ± 0.24ab
      India-A-23.58 ± 0.110.55 ± 0.060.8 ± 0.040.49 ± 0.090 ± 05.41 ± 0.3ghijklmnop0.38 ± 0.050.74 ± 0.070.48 ± 0.10.02 ± 00.03 ± 0.010.03 ± 01.68 ± 0.23fgh
      India-A-33.62 ± 0.050.73 ± 0.071.01 ± 0.112.77 ± 0.010 ± 08.13 ± 0.25b0.27 ± 0.020.49 ± 0.020.32 ± 0.020.01 ± 00.02 ± 00.02 ± 01.13 ± 0.07ijk
      India-A-43.75 ± 0.060.81 ± 0.12.6 ± 0.072.77 ± 0.250 ± 09.93 ± 0.49a0.15 ± 00.27 ± 0.010.19 ± 0.020 ± 00.01 ± 0.010 ± 0.010.62 ± 0.03lmnop
      Indonesia-A-12.9 ± 0.280.33 ± 0.011.08 ± 0.061.03 ± 0.050 ± 0.015.33 ± 0.39ghijklmnop0.67 ± 0.021.51 ± 0.080.81 ± 0.020.05 ± 0.010.09 ± 0.010.09 ± 0.013.22 ± 0.14a
      Indonesia-A-23.53 ± 0.170.59 ± 0.081.05 ± 0.061.11 ± 0.070.02 ± 0.016.29 ± 0.27defghij0.5 ± 0.011.11 ± 0.020.65 ± 0.070.03 ± 0.010.06 ± 0.010.05 ± 02.41 ± 0.12cd
      Indonesia-A-33.9 ± 0.160.51 ± 0.040.71 ± 0.151.47 ± 0.040 ± 06.57 ± 0.38cdefgh0.31 ± 0.010.58 ± 0.010.36 ± 0.010.01 ± 00.03 ± 00.03 ± 01.32 ± 0.04hij
      Indonesia-A-44.87 ± 0.230.73 ± 0.071.01 ± 0.041.19 ± 0.060 ± 07.8 ± 0.39bc0.15 ± 00.25 ± 0.010.17 ± 00 ± 00 ± 0.010 ± 0.010.58 ± 0.01lmnop
      Uganda-A-12.92 ± 0.190.57 ± 0.111.47 ± 0.241.52 ± 0.240 ± 0.016.48 ± 0.78cdefghi0.6 ± 01.28 ± 00.74 ± 00.04 ± 00.07 ± 00.07 ± 02.79 ± 0.02bc
      Uganda-A-23.07 ± 0.110.55 ± 0.151.81 ± 0.232.2 ± 0.160.01 ± 0.017.62 ± 0.64bcde0.4 ± 0.010.86 ± 0.040.49 ± 0.010.02 ± 00.04 ± 00.04 ± 01.85 ± 0.07ef
      Uganda-A-33.47 ± 0.080.55 ± 0.152.04 ± 0.132.5 ± 0.220.01 ± 0.018.56 ± 0.4ab0.26 ± 0.010.51 ± 00.32 ± 00.02 ± 00.02 ± 00.02 ± 01.14 ± 0.02ijk
      Uganda-A-43.57 ± 0.110.48 ± 0.10.61 ± 0.041.7 ± 0.140.02 ± 06.38 ± 0.38cdefghij0.14 ± 0.010.24 ± 0.020.17 ± 0.010 ± 00 ± 00 ± 00.56 ± 0.04lmnop
      Vietnam-A-11.28 ± 0.110.32 ± 0.051.55 ± 0.132.21 ± 0.180.01 ± 05.36 ± 0.46ghijklmnop0.48 ± 0.041.18 ± 0.080.59 ± 0.020.04 ± 00.08 ± 0.010.08 ± 02.45 ± 0.15cd
      Vietnam-A-21.46 ± 0.050.3 ± 0.041.27 ± 0.083.1 ± 0.010.02 ± 06.14 ± 0.09fghijkl0.29 ± 0.010.65 ± 0.020.38 ± 0.040.02 ± 00.03 ± 00.04 ± 0.011.41 ± 0.08ghi
      Vietnam-A-31.73 ± 0.060.25 ± 0.031 ± 0.013.2 ± 0.070.01 ± 0.016.19 ± 0.18efghijk0.17 ± 0.010.35 ± 0.020.23 ± 0.040.01 ± 00.02 ± 00.02 ± 00.8 ± 0.07klmno
      Vietnam-A-41.97 ± 0.11.11 ± 0.040.79 ± 0.033.41 ± 0.040.03 ± 0.017.3 ± 0.21bcdef0.11 ± 0.020.19 ± 0.020.13 ± 0.020 ± 00 ± 00 ± 00.42 ± 0.06op
      Brazil-R-12.19 ± 0.120.1 ± 0.010.39 ± 0.030.14 ± 0.020 ± 0.012.83 ± 0.18s0.65 ± 0.041.43 ± 0.040.8 ± 0.020.05 ± 00.09 ± 00.09 ± 0.013.11 ± 0.11ab
      Brazil-R-22.66 ± 0.380.39 ± 0.040.27 ± 0.040 ± 00.01 ± 0.013.33 ± 0.37rs0.39 ± 0.030.78 ± 0.050.48 ± 0.020.03 ± 00.04 ± 00.04 ± 01.75 ± 0.1efg
      Brazil-R-33.04 ± 0.10.73 ± 0.070.16 ± 0.040.41 ± 0.020 ± 04.33 ± 0.24nopqr0.16 ± 00.29 ± 0.010.2 ± 0.010 ± 00 ± 0.010 ± 0.010.66 ± 0.01lmnop
      Brazil-R-43.8 ± 0.250.3 ± 0.040.09 ± 0.020.38 ± 00 ± 04.58 ± 0.27mnopqr0.08 ± 0.010.13 ± 0.010.09 ± 0.010 ± 00 ± 00 ± 00.29 ± 0.03p
      India-R-13.06 ± 0.210.28 ± 0.040.28 ± 0.050 ± 00 ± 03.62 ± 0.3qrs0.5 ± 0.010.99 ± 0.030.63 ± 0.040.06 ± 0.020.1 ± 00.09 ± 02.36 ± 0.1d
      India-R-23.44 ± 0.190.85 ± 0.090.23 ± 0.030 ± 00 ± 04.52 ± 0.24mnopqr0.29 ± 00.57 ± 0.040.36 ± 0.020.02 ± 0.010.04 ± 00.04 ± 01.33 ± 0.08hij
      India-R-33.15 ± 0.211.01 ± 0.030.22 ± 0.010.4 ± 0.030.02 ± 0.014.8 ± 0.15klmnopq0.21 ± 00.39 ± 0.030.26 ± 0.010.01 ± 00.03 ± 0.010.02 ± 00.92 ± 0.06jklm
      India-R-43.87 ± 0.191.26 ± 0.140.26 ± 0.060.5 ± 0.040.02 ± 05.91 ± 0.43fghijklm0.12 ± 0.010.21 ± 0.010.14 ± 00.01 ± 00.01 ± 00.01 ± 00.51 ± 0.03mnop
      Indonesia-R-12.74 ± 0.220.32 ± 0.030.68 ± 0.050.34 ± 0.060.01 ± 0.014.09 ± 0.37pqrs0.5 ± 0.020.99 ± 0.020.62 ± 0.020.05 ± 00.09 ± 00.09 ± 0.012.32 ± 0.08d
      Indonesia-R-23.14 ± 0.150.43 ± 0.020.47 ± 0.070.23 ± 00.01 ± 0.014.27 ± 0.21opqr0.33 ± 0.010.68 ± 0.050.45 ± 0.060.03 ± 0.010.08 ± 0.010.05 ± 0.011.63 ± 0.14fgh
      Indonesia-R-33.63 ± 0.110.47 ± 0.010.29 ± 0.020.33 ± 0.020.01 ± 0.014.73 ± 0.15lmnopqr0.14 ± 0.020.25 ± 0.020.16 ± 0.010.01 ± 00.01 ± 00.01 ± 00.58 ± 0.05lmnop
      Indonesia-R-43.66 ± 3.780.16 ± 0.480.22 ± 0.60.38 ± 1.440.01 ± 0.0044.43 ± 0.37nopqr0.1 ± 0.30.17 ± 0.5770.12 ± 0.3530 ± 0.0110 ± 0.0240 ± 0.0240.4 ± 1.289op
      Uganda-R-13.27 ± 0.150.31 ± 0.040.54 ± 0.060.25 ± 0.040.01 ± 04.38 ± 0.29nopqr0.5 ± 0.011.08 ± 0.050.67 ± 0.070.05 ± 0.010.08 ± 0.010.08 ± 02.46 ± 0.15cd
      Uganda-R-23.52 ± 0.20.25 ± 0.130.45 ± 0.040.3 ± 0.020.02 ± 04.53 ± 0.06mnopqr0.39 ± 0.030.77 ± 0.060.5 ± 0.060.03 ± 0.010.05 ± 0.010.05 ± 01.78 ± 0.18efg
      Uganda-R-33.9 ± 0.330.16 ± 0.010.11 ± 0.010.37 ± 0.080.02 ± 04.56 ± 0.41mnopqr0.1 ± 0.120.35 ± 0.020.27 ± 0.060 ± 00.02 ± 00.01 ± 0.010.76 ± 0.05klmno
      Uganda-R-44.01 ± 0.170.25 ± 0.130.11 ± 0.010.41 ± 0.030.02 ± 0.014.8 ± 0.07klmnopq0.07 ± 0.020.15 ± 0.010.1 ± 0.010 ± 00 ± 00 ± 00.32 ± 0.03p
      Vietnam-R-13.96 ± 0.080.16 ± 0.080.46 ± 0.070.38 ± 0.040 ± 04.96 ± 0.1jklmnopq0.7 ± 0.021.42 ± 0.050.88 ± 0.050.08 ± 00.15 ± 0.010.14 ± 03.36 ± 0.14a
      Vietnam-R-23.94 ± 0.210.5 ± 0.040.2 ± 00.48 ± 0.040.01 ± 0.015.13 ± 0.13ijklmnop0.3 ± 0.010.54 ± 0.010.37 ± 0.020.02 ± 00.08 ± 00 ± 01.31 ± 0.04hij
      Vietnam-R-34.69 ± 0.140.81 ± 0.130.19 ± 0.020.5 ± 0.060 ± 06.19 ± 0.35efghijk0.2 ± 00.36 ± 00.24 ± 00.01 ± 00.02 ± 00.01 ± 0.010.85 ± 0.02klmn
      Vietnam-R-44.92 ± 0.120.5 ± 0.010.14 ± 0.010 ± 00 ± 05.56 ± 0.13ghijklmno0.07 ± 00.12 ± 00.08 ± 00 ± 00 ± 00 ± 00.28 ± 0.01p
      *A: Arabica bean; R: Robusta bean;
      1: medium light, 2: medium, 3: medium dark; 4: dark;
      Letter code: Samples with the same letter code are not significantly different (P < 0.05).

      Figure 2.  Organic acid and CACs concentration of coffee beans (g/100 g). (a) & (b), organic acid concentration; (c) & (d), CACs concentration. Blue represents Arabica beans, Orange represents Robusta beans. 1, medium light; 2, medium; 3, medium dark; 4, dark.

      According to Fig. 2a, for most coffee beans, the total organic acid concentration increased with the increase of roasting degree. However, when the roasting degree of Arabica beans from Uganda and Robusta beans from Vietnam was dark, the concentration of total organic acids fell significantly, which corresponds to the results of Wang[15]. And the significant decrease of total concentration was mainly as a result of the decease of citric acid and succinic acid, which are easily decomposed at high temperature[8]. Between the groups of different species, the value of Robusta beans was lower, and the value was significantly different (Fig. 2b). While the value of Arabica was not different from each other. Thus, production area may influence the organic acid concentration of Robusta beans.

      For the concentration of CACs of each coffee beans, it had an obvious negative correlation with roasting degree. With regard to production area, there was no significant influence on the CACs concentration of two species of coffee beans (Fig. 2d). Also, the value of Arabica beans was similar to that of Robusta. Therefore, the concentration of CACs may only be influenced by roasting degree.

    • VCs are the main contributors to the odor of coffee, usually related to roasted coffee oil[16]. VCs can be composed of various chemical compounds, such as aldehydes, esters, ketones, alcohols, hydrocarbons, phenols, carboxylic acids, pyridine, pyrazines, furans and so on. The result of each volatile compound of each sample are shown in Supplemental Table S1. The total amount of VCs of coffee beans are shown in Fig. 3. For different species of coffee beans, there were some unique compounds. Arabica beans contained furfural and butyraldehyde isopropyl ester, and Robusta beans contained methylheptenone. Also, the total amount of VCs were also different. As the value of Arabica beans was higher than that of Robusta beans, the total amount of VCs of most coffee beans increased with the increase of roasting degree. As for the production area, there was no significant difference between each species of coffee beans (Fig. 3b).

      Figure 3.  Total amount of VCs of different coffee beans. Blue represents Arabica beans, Orange represents Robusta beans. 1, medium light; 2, medium; 3, medium dark; 4, dark.

    • PCA was performed on five indexes (protein concentration, fat concentration, total organic acid concentration, total CACs concentration and total amount of VCs) of 40 samples, and the results are shown in Table 6. Three principal components were extracted, and the cumulative variance contribution rate was 93.1%. Based on PC1 and PC2, a discriminant analysis was performed among the 40 samples, shown in Fig. 4. The results clearly showed that Arabica bean and Robusta bean, and the beans with different roasting degrees were discriminated by PC1 and PC2. While coffee beans from the same production area did not cluster together clearly. Thus, species and roasting degrees can distinguish coffee beans better than production area, which corresponds to the above results. Coffee beans produced in different areas may have the same or similar origin. In addition, Brazil, India, Indonesia, Uganda and Vietnam are located on a similar latitude. So, the same species of coffee bean from these production areas is mostly likely to show similar characteristics.

      Table 6.  Loading table of each index of coffee bean

      IndexPC1PC2PC3
      Protein−0.390.613−0.162
      Fat0.4890.2490.501
      Total organic acids0.501−0.097−0.806
      Total CACs0.272−0.740.118
      Total VCs0.532−0.0660.241
      RVC (%)60.126.56.6
      Cumulative RVC (%)93.1

      Figure 4.  Discriminant results of coffee beans.

    • In this research, coffee beans of two species (Arabica beans and Robusta beans) from five different production areas (Brazil, India, Indonesia, Uganda and Vietnam) with four different roasting degrees (medium light, medium, medium dark and dark), and a total of 40 samples, were used. The protein, fat, organic acids, CACs and VCs were measured to investigate the difference among the samples. The results suggested that coffee beans of two species had obviously different substance concentrations, as Arabica coffee beans had higher concentrations of fat and organic acids, and total amount of VCs, while Robusta beans had higher concentrations of protein. Due to the increasing loss of moisture, the concentration of protein, fat, organic acids, and the total amount of VCs of coffee beans increased with the increase of roasting degree. The concentration of CACs was lower, while the roasting degree of coffee beans was higher, as CACs decomposed at high temperature. Compared to species and roasting degree, production area influenced only part of the index. The concentration of protein of two species of coffee beans and the concentration of organic acids of Robusta beans were affected significantly by production area. For further conclusions on the influence of production area on coffee beans, further research is required. Based on the results of the measurement of protein, fat, organic acids, CACs and VCs, PCA was performed to illustrate the correlation among species, production area and roasting degree with coffee beans. The discriminant analysis indicated that species and roasting degrees could differentiate the coffee beans clearly. While production area could not differentiate the coffee beans well.

      The results of this research conclude the difference between Arabica and Robusta beans, and coffee beans with different roasting degrees from different production areas. It can provide a theoretical basis for coffee bean selection for the relevant industry.

      • The authors declare that they have no conflict of interest.
      • Copyright: © 2022 by the author(s). Exclusive Licensee Maximum Academic Press, Fayetteville, GA. This article is an open access article distributed under Creative Commons Attribution License (CC BY 4.0), visit https://creativecommons.org/licenses/by/4.0/.
    Figure (4)  Table (6) References (16)
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    Liu X, Fei Y, Wang W, Lei S, Cheng C, et al. 2022. Physicochemical difference of coffee beans with different species, production areas and roasting degrees. Beverage Plant Research 2: 7 doi: 10.48130/BPR-2022-0007
    Liu X, Fei Y, Wang W, Lei S, Cheng C, et al. 2022. Physicochemical difference of coffee beans with different species, production areas and roasting degrees. Beverage Plant Research 2: 7 doi: 10.48130/BPR-2022-0007

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