Multivariate Analysis of Essential Oil Composition of Artemisia annua L. Collected from Different Locations in Korea
Abstract
:1. Introduction
2. Results and Discussion
2.1. Yield and Color of Korean A. annua Essential Oils
2.2. Chemical Variations of Korean A. annua Essential Oils
2.3. Multivariate Analysis
2.3.1. Cluster Analysis
2.3.2. Principal Component Analysis (PCA)
2.3.3. Correlation Analysis
3. Materials and Methods
3.1. Collection and Cultivation of Korean A. annua Seeds
3.2. Extraction of Essential Oils
3.3. Identification of Essential Oil Components by GC-MS Analysis
3.4. Statistical Analysis
4. Conclusions
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Sample Availability
References
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No. | Samples | Yield (%) | Color | No. | Samples | Yield (%) | Color | No. | Samples | Yield (%) | Color |
---|---|---|---|---|---|---|---|---|---|---|---|
1 | AA1 | 0.237 | Y | 36 | AA40 | 0.288 | DY | 71 | AA78 | 0.689 | DY |
2 | AA2 | 0.527 | DY | 37 | AA41 | 0.046 | Y | 72 | AA80 | 0.645 | PY |
3 | AA3 | 0.142 | DY | 38 | AA42 | 0.107 | DY | 73 | AA82 | 0.697 | PY |
4 | AA4 | 0.311 | Y | 39 | AA43 | 0.076 | DY | 74 | AA83 | 0.664 | Y |
5 | AA5 | 0.723 | PY | 40 | AA44 | 0.038 | PY | 75 | AA84 | 0.647 | PY |
6 | AA6 | 0.227 | DY | 41 | AA45 | 0.038 | Y | 76 | AA85 | 0.617 | Y |
7 | AA7 | 0.088 | DY | 42 | AA46 | 0.041 | DY | 77 | AA86 | 0.500 | DY |
8 | AA11 | 0.360 | Y | 43 | AA47 | 0.060 | Y | 78 | AA87 | 0.745 | Y |
9 | AA12 | 0.377 | DY | 44 | AA48 | 0.058 | DY | 79 | AA88 | 0.690 | PY |
10 | AA13 | 0.223 | DY | 45 | AA49 | 0.059 | Y | 80 | AA89 | 0.561 | PY |
11 | AA14 | 0.440 | PY | 46 | AA50 | 0.039 | DY | 81 | AA90 | 0.932 | PY |
12 | AA15 | 0.335 | Y | 47 | AA51 | 0.064 | Y | 82 | AA91 | 1.088 | PY |
13 | AA16 | 0.330 | PY | 48 | AA52 | 0.037 | DY | 83 | AA92 | 0.629 | PY |
14 | AA17 | 0.435 | Y | 49 | AA53 | 0.049 | Y | 84 | AA93 | 0.792 | PY |
15 | AA18 | 0.273 | DY | 50 | AA54 | 0.063 | DY | 85 | AA94 | 0.895 | PY |
16 | AA20 | 0.194 | DY | 51 | AA55 | 0.085 | DY | 86 | AA95 | 0.983 | PY |
17 | AA21 | 0.367 | DY | 52 | AA56 | 0.041 | PY | 87 | AA96 | 1.063 | PY |
18 | AA22 | 0.257 | DY | 53 | AA57 | 0.059 | PY | 88 | AA97 | 1.060 | PY |
19 | AA23 | 0.426 | Y | 54 | AA58 | 0.050 | PY | 89 | AA98 | 0.818 | PY |
20 | AA24 | 0.490 | DY | 55 | AA59 | 0.061 | Y | 90 | AA99 | 0.751 | PY |
21 | AA25 | 0.533 | Y | 56 | AA60 | 0.046 | PY | 91 | AA100 | 0.744 | PY |
22 | AA26 | 0.492 | DY | 57 | AA61 | 0.630 | Y | 92 | AA101 | 0.767 | PY |
23 | AA27 | 0.305 | DY | 58 | AA62 | 0.720 | PY | 93 | AA102 | 0.913 | PY |
24 | AA28 | 0.526 | DY | 59 | AA63 | 0.772 | PY | 94 | AA103 | 0.798 | PY |
25 | AA29 | 0.519 | Y | 60 | AA64 | 0.827 | PY | 95 | AA104 | 0.762 | PY |
26 | AA30 | 0.213 | Y | 61 | AA65 | 0.624 | PY | 96 | AA105 | 0.574 | PY |
27 | AA31 | 0.369 | Y | 62 | AA66 | 0.581 | PY | 97 | AA106 | 0.771 | PY |
28 | AA32 | 0.137 | DY | 63 | AA67 | 0.652 | PY | 98 | AA107 | 0.903 | PY |
29 | AA33 | 0.380 | Y | 64 | AA68 | 0.566 | Y | 99 | AA108 | 0.561 | PY |
30 | AA34 | 0.355 | Y | 65 | AA69 | 0.606 | PY | 100 | AA109 | 0.663 | PY |
31 | AA35 | 0.311 | DY | 66 | AA70 | 0.624 | PY | 101 | AA110 | 0.566 | PY |
32 | AA36 | 0.267 | DY | 67 | AA71 | 0.650 | PY | 102 | AA111 | 0.536 | PY |
33 | AA37 | 0.214 | DY | 68 | AA72 | 0.891 | PY | 103 | AA112 | 0.926 | PY |
34 | AA38 | 0.361 | DY | 69 | AA74 | 0.501 | Y | ||||
35 | AA39 | 0.337 | Y | 70 | AA75 | 0.910 | PY |
Chemotypes | Content Ratio (%) | Samples |
---|---|---|
Artemisia ketone (75) | 20.51–83.82 | AA1, AA2, AA4, AA5, AA6, AA11, AA12, AA13, AA14, AA15, AA16, AA17, AA20, AA21 AA22, AA24, AA25, AA26, AA27, AA28, AA32, AA33, AA34, AA35, AA36, AA37, AA38, AA39, AA40, AA61, AA62, AA63, AA64, AA65, AA66, AA67, AA68, AA69, AA70, AA71, AA72, AA74, AA75, AA78, AA80, AA82, AA83, AA85, AA86, AA87, AA88, AA89, AA90, AA91, AA92, AA93, AA94, AA95, AA96, AA97, AA98, AA99, AA100, AA101, AA102, AA103, AA104, AA105, AA106, AA107, AA108, AA109, AA110, AA111, AA112 |
Camphor (1) | 25.05 | AA30 |
β-Cubebene (5) | 13.90–22.52 | AA47, AA48, AA51, AA55, AA57 |
Eucalyptol (4) | 15.07–43.01 | AA23, AA29, AA31, AA84 |
α-Pinene (1) | 21.16 | AA18 |
β-Selinene (17) | 20.05–46.29 | AA3, AA7, AA41, AA42, AA43, AA44, AA45, AA46, AA49, AA50, AA52, AA53, AA54, AA56, AA58, AA59, AA60 |
Group | Major Compound | Chemical Characteristics |
---|---|---|
I | Artemisia ketone | Monoterpenoids content ratio in the essential oil is dominant (monoterpenoids content ratio > 64%; artemisia ketone ratio > 41%). |
II | β-Selinene | Sesquiterpenoids content ratio in the essential oil is dominant(sesquiterpenoids content ratio > 37%; β-selinene > 20%) |
III | Eucalyptol, β-cubebene | Monoterpenoids and sesquiterpenoids content ratio in the essential oil is similar (monoterpenoids content:sesquiterpenoids content = 1:1) |
No. | Chemical Name | Code | Principal Components | ||
---|---|---|---|---|---|
PC1 | PC2 | PC3 | |||
1 | Santolina triene | C1 | −0.540 | 0.092 | −0.066 |
2 | α-Pinene | C2 | 0.249 | 0.408 | 0.088 |
3 | Camphene | C3 | 0.303 | 0.526 | 0.085 |
4 | β-Pinene | C4 | 0.174 | 0.654 | 0.054 |
5 | Yomogi alcohol | C5 | −0.516 | 0.148 | 0.126 |
6 | α-Terpinene | C6 | 0.264 | 0.771 | −0.115 |
7 | p-Cymene | C7 | 0.403 | 0.315 | 0.186 |
8 | Limonene | C8 | 0.269 | 0.569 | −0.185 |
9 | Eucalyptol | C9 | 0.113 | 0.807 | −0.523 |
10 | Artemisia ketone | C10 | −0.998 | −0.063 | −0.026 |
11 | Sabinene hydrate | C11 | 0.057 | 0.446 | −0.291 |
12 | Artemisia alcohol | C12 | −0.619 | 0.105 | 0.027 |
13 | 3-Isopentenyl isovalerate | C13 | −0.288 | 0.133 | −0.094 |
14 | Pinocarveol | C14 | 0.245 | 0.382 | 0.093 |
15 | Camphor | C15 | 0.325 | 0.395 | 0.028 |
16 | Pinocarvone | C16 | 0.148 | 0.326 | 0.089 |
17 | Terpinen-4-ol | C17 | 0.361 | 0.774 | −0.110 |
18 | α-Terpineol | C18 | 0.161 | 0.810 | −0.401 |
19 | 3-Hexenyl isovalerate | C19 | −0.167 | 0.265 | −0.168 |
20 | α-Longipinene | C20 | −0.019 | −0.046 | −0.293 |
21 | α-Copaene | C21 | 0.267 | 0.010 | 0.229 |
22 | Benzyl isovalerate | C22 | 0.641 | −0.371 | −0.006 |
23 | β-Cubebene | C23 | 0.687 | −0.262 | 0.442 |
24 | β-Caryophyllene | C24 | 0.716 | −0.245 | 0.275 |
25 | β-Farnesene | C25 | −0.418 | 0.279 | −0.064 |
26 | α-Humulene | C26 | 0.292 | 0.048 | 0.189 |
27 | β-Chamigrene | C27 | −0.241 | 0.199 | 0.010 |
28 | β-Selinene | C28 | 0.708 | −0.598 | −0.371 |
29 | γ-Elemene | C29 | 0.647 | −0.093 | 0.411 |
30 | Butylated hydroxytoluene | C30 | −0.243 | 0.038 | 0.136 |
31 | δ-Cadinene | C31 | 0.670 | −0.221 | 0.188 |
32 | Caryophyllene oxide | C32 | 0.469 | −0.193 | 0.261 |
33 | α-Muurolol | C33 | 0.673 | −0.380 | 0.311 |
34 | Vulgarone B | C34 | −0.331 | 0.160 | −0.144 |
35 | Lanceol | C35 | 0.611 | −0.313 | 0.399 |
Proportion of variance (%) | 82.554 | 8.738 | 3.616 | ||
Cumulative proportion (%) | 82.554 | 91.283 | 94.899 |
PC | Correlation | Relevant Chemicals |
---|---|---|
PC1 | Positive (+) | β-Caryophyllene, β-selinene, β-cubebene, α-muurolol |
Negative (−) | Artemisia ketone, artemisia alcohol | |
PC2 | Positive (+) | α-Terpineol, eucalyptol, terpinene-4-ol, α-terpinene |
No. | Sample Code | Sampling Site | No. | Sample Code | Sampling Site | No. | Sample Code | Sampling Site |
---|---|---|---|---|---|---|---|---|
1 | AA1 | Wonju | 39 | AA39 | Ulsan | 77 | AA77 | Yanggu |
2 | AA2 | Hwacheon | 40 | AA40 | Bonghwa | 78 | AA78 | Yanggu |
3 | AA3 | Chuncheon | 41 | AA41 | Imsil | 79 | AA79 | Yanggu |
4 | AA4 | Yangyang | 42 | AA42 | Imsil | 80 | AA80 | Yanggu |
5 | AA5 | Sokcho | 43 | AA43 | Jeonju | 81 | AA81 | Yanggu |
6 | AA6 | Goseong | 44 | AA44 | Nonsan | 82 | AA82 | Yanggu |
7 | AA7 | Inje | 45 | AA45 | Daejeon | 83 | AA83 | Seoul |
8 | AA8 | Yanggu | 46 | AA46 | Hanam | 84 | AA84 | Seoul |
9 | AA9 | Yangpyeong | 47 | AA47 | Pyeongtaek | 85 | AA85 | Sungnam |
10 | AA10 | Jeongseon | 48 | AA48 | Sejong | 86 | AA86 | Sungnam |
11 | AA11 | Hongcheon | 49 | AA49 | Sejong | 87 | AA87 | Incheon |
12 | AA12 | Hoengseong | 50 | AA50 | Hanam | 88 | AA88 | Incheon |
13 | AA13 | Pyeongchang | 51 | AA51 | Ulsan | 89 | AA89 | Incheon |
14 | AA14 | Namyangju | 52 | AA52 | Ulsan | 90 | AA90 | Daejeon |
15 | AA15 | Pocheon | 53 | AA53 | Bonghwa | 91 | AA91 | Yeongcheon |
16 | AA16 | Gapyeong | 54 | AA54 | Bonghwa | 92 | AA92 | Mungyeong |
17 | AA17 | Chungju | 55 | AA55 | Gwangju | 93 | AA93 | Bonghwa |
18 | AA18 | Danyang | 56 | AA56 | Yongin | 94 | AA94 | Gimcheon |
19 | AA19 | Jecheon | 57 | AA57 | Hongcheon | 95 | AA95 | Bonghwa |
20 | AA20 | Yeongwol | 58 | AA58 | Seoul | 96 | AA96 | Yeongju |
21 | AA21 | Hongcheon | 59 | AA59 | Seoul | 97 | AA97 | Ulsan |
22 | AA22 | Hongcheon | 60 | AA60 | Samcheok | 98 | AA98 | Ulsan |
23 | AA23 | Chuncheon | 61 | AA61 | Seoul | 99 | AA99 | Ulsan |
24 | AA24 | Chuncheon | 62 | AA62 | Seoul | 100 | AA100 | Ulsan |
25 | AA25 | Hwacheon | 63 | AA63 | Seoul | 101 | AA101 | Changwon |
26 | AA26 | Hwacheon | 64 | AA64 | Seoul | 102 | AA102 | Changwon |
27 | AA27 | Chuncheon | 65 | AA65 | Seoul | 103 | AA103 | Changnyeong |
28 | AA28 | Chuncheon | 66 | AA66 | Seoul | 104 | AA104 | Sacheon |
29 | AA29 | Hongcheon | 67 | AA67 | Seoul | 105 | AA105 | Guri |
30 | AA30 | Pyeongtaek | 68 | AA68 | Anyang | 106 | AA106 | Gapyeong |
31 | AA31 | Yongin | 69 | AA69 | Goyang | 107 | AA107 | Ganghwa |
32 | AA32 | Wonju | 70 | AA70 | Nonsan | 108 | AA108 | Paju |
33 | AA33 | Incheon | 71 | AA71 | Yeoju | 109 | AA109 | Inje |
34 | AA34 | Anyang | 72 | AA72 | Yeoju | 110 | AA110 | Ansan |
35 | AA35 | Seoul | 73 | AA73 | Yanggu | 111 | AA111 | Yongin |
36 | AA36 | Changwon | 74 | AA74 | Yanggu | 112 | AA112 | Chulwon |
37 | AA37 | Ulsan | 75 | AA75 | Yanggu | |||
38 | AA38 | Ulsan | 76 | AA76 | Yanggu |
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Hong, M.; Kim, M.; Jang, H.; Bo, S.; Deepa, P.; Sowndhararajan, K.; Kim, S. Multivariate Analysis of Essential Oil Composition of Artemisia annua L. Collected from Different Locations in Korea. Molecules 2023, 28, 1131. https://doi.org/10.3390/molecules28031131
Hong M, Kim M, Jang H, Bo S, Deepa P, Sowndhararajan K, Kim S. Multivariate Analysis of Essential Oil Composition of Artemisia annua L. Collected from Different Locations in Korea. Molecules. 2023; 28(3):1131. https://doi.org/10.3390/molecules28031131
Chicago/Turabian StyleHong, Minji, Minju Kim, Haejung Jang, Sela Bo, Ponnuvel Deepa, Kandhasamy Sowndhararajan, and Songmun Kim. 2023. "Multivariate Analysis of Essential Oil Composition of Artemisia annua L. Collected from Different Locations in Korea" Molecules 28, no. 3: 1131. https://doi.org/10.3390/molecules28031131
APA StyleHong, M., Kim, M., Jang, H., Bo, S., Deepa, P., Sowndhararajan, K., & Kim, S. (2023). Multivariate Analysis of Essential Oil Composition of Artemisia annua L. Collected from Different Locations in Korea. Molecules, 28(3), 1131. https://doi.org/10.3390/molecules28031131