Ensemble hologram quantitative structure activity relationship model of the chromatographic retention index of aldehydes and ketones

doi:10.3724/SP.J.1123.2020.06011

Abstract

Abstract:

Chromatographic retention index (RI) is an important parameter for describing the retention behavior of substances in chromatographic analysis. Experimentally determining the RI values of different aldehyde and ketone compounds in all kinds of polar stationary phases is expensive and time consuming. Quantitative structure activity relationship (QSAR) is an important chemometric technique that has been widely used to correlate the properties of chemicals to their molecular structures. Irrespective of whether the properties of a molecule have been experimentally determined, they can be calculated using QSAR models. It is therefore necessary and advisable to establish the QSAR model for predicting the RI value of aldehydes and ketones. Hologram QSAR (HQSAR) is a highly efficient QSAR approach that can easily generate QSAR models with good statistics and high prediction accuracy. A specific fragment of fingerprint, known as a molecular hologram, is proposed in the HQSAR approach and used as a structural descriptor to build the proposed QSAR model. In general, individual HQSAR models are built in QSAR researches. However, individual QSAR models are usually affected by underfitting and overfitting. The ensemble modeling method, which integrate several individual models through certain consensus strategies, can overcome the shortcomings of individual models. It is worth studying whether ensemble modeling can improve the prediction ability of the HQSAR method in order to build more accurate and reliable QSAR models.
Therefore, this study investigates the QSAR model for chromatographic RI of aldehydes and ketones using ensemble modeling and the HQSAR method. Two individual HQSAR models comprising 34 compounds in two stationary phases, DB-210 and HP-Innowax, were established. The prediction ability of the two established models was assessed by external test set validation and leave-one-out cross validation (LOO-CV). The investigated 34 compounds were randomly assigned into two groups. Group Ⅰ comprised 26 compounds, and Group Ⅱ comprised 8 compounds. In the validation of the external test set, Group Ⅰ was employed to manually optimize the two fragment parameters (fragment distinction (FD) and fragment size (FS)) and build the HQSAR models. Group Ⅱ was used as the test set to assess the predictive performance of the developed models. For the DB-210 stationary phase, the optimal individual HQSAR model was obtained while setting the FD and FS to “donor/acceptor atoms (DA)” and 1-9, respectively. For the HP-Innowax stationary phase, the optimal individual HQSAR model was obtained by setting the FD and FS to “DA” and 4-7 respectively. The squared correlation coefficient of cross validation ( $q cv 2$ ), concordance correlation coefficient (CCC), squared correlation coefficient of external validation ( $q ext 2$ ), predictive squared correlation coefficient ( $Q F 2 2$ and $Q F 3 2$ ) of the two models for predicting the RI value were 0.935 and 0.909, 0.953 and 0.960, 0.925 and 0.927, 0.922 and 0.918, and 0.931 and 0.927, respectively. The results of the two validations show that there is a quantitative relationship between the molecular structure of these compounds and the RI value, and the HQSAR model is capable of modeling this relationship. Second, the ensemble HQSAR models were established using the four individual HQSAR models with the highest accuracy as the sub-models through arithmetic averaging. The ensemble HQSAR models were validated by external test set validation and LOO-CV. The $q cv 2$ , CCC, $q ext 2$ , $Q F 2 2$ , and $Q F 3 2$ for predicting the RI values of the DB-210 and HP-Innowax stationary phases were 0.927 and 0.919, 0.956 and 0.979, 0.929 and 0.963, 0.927 and 0.958, and 0.935 and 0.963, respectively. Compared to the individual HQSAR models, the established ensemble HQSAR models show better robustness and accuracy, thus establishing that ensemble modeling is an effective approach. The combination of HQSAR and the ensemble modeling method is a practicable and promising method for studying and predicting the RI values of aldehydes and ketones.

Key words: ensemble modeling, hologram quantitative structure-activity relationship, aldehydes and ketones, chromatographic retention index

CLC Number:

O658

LEI Bin, ZANG Yunlei, XUE Zhiwei, GE Yiqing, LI Wei, ZHAI Qian, JIAO Long. Ensemble hologram quantitative structure activity relationship model of the chromatographic retention index of aldehydes and ketones[J]. Chinese Journal of Chromatography, 2021, 39(3): 331-337.

Figures/Tables 4

Table 1 Experimental[20] and predicted retention indices of the investigated aldehydes and ketones on two chromatographic columns

Group	Compound	RI of DB-210						RI of HP-Innowax
		Exp	Pred		RE/%			Pred	Pred	RE/%
		Exp	Ind	Ens	Ind	Ens	Ind	Pred	Ens	Ind	Ens
Ⅰ	acetone	792.9	764.8	792.9	-3.54	0.00		835.0				877.3	879.1	5.07	5.28
	2-butanone	882.1	869.9	872.6	-1.38	-1.08		919.8				917.5	915.6	-0.25	-0.46
	3-methyl-2-butanone	943.3	943.8	934.1	0.05	-0.98		949.4				951.8	948.4	0.25	-0.11
	3-pentanone	960.8	970.2	959.3	0.98	-0.16		996.9				972.3	968.0	-2.47	-2.90
	3,3-dimethyl-2-butanone	992.0	991.6	982.8	-0.04	-0.93		968.5				904.8	893.7	-6.58	-7.72
	4-methyl-2-pentanone	1027.1	1004.2	995.6	-2.23	-3.07		1025.2				1041.4	1033.6	1.58	0.82
	2,4-dimethyl-3-pentanone	1038.5	1084.2	1077.8	4.40	3.78		1014.8				971.1	1010.7	-4.31	-0.40
	2-hexanone	1081.5	1079.0	1075.6	-0.23	-0.55		1097.2				1100.2	1085.6	0.27	-1.06
	4-heptanone	1134.5	1126.9	1122.3	-0.67	-1.08		1139.4				1148.0	1156.6	0.75	1.51
	5-methyl-2-hexanone	1161.3	1122.9	1118.4	-3.31	-3.69		1156.1				1139.5	1148.8	-1.44	-0.63
	2-heptanone	1184.3	1186.6	1185.7	0.19	0.12		1195.8				1211.3	1183.5	1.30	-1.03
	2-methyl-3-heptanone	1192.4	1173.2	1164.1	-1.61	-2.37		1178.7				1201.5	1210.8	1.93	2.72
	5-methyl-3-heptanone	1026.9	1172.2	1184.1	14.15	15.31		1200.1				1166.2	1190.4	-2.82	-0.81
	3-octanone	1255.5	1252.3	1254.0	-0.25	-0.12		1265.5				1262.5	1257.1	-0.24	-0.66
	5-nonanone	1342.6	1310.0	1325.4	-2.43	-1.28		1334.1				1345.1	1361.4	0.82	2.05
	acrolein	743.7	770.1	776.1	3.55	4.36		867.0				853.0	855.0	-1.61	-1.38
	isobutanal	803.7	839.9	839.3	4.50	4.43		830.4				836.8	877.7	0.77	5.70
	butanal	843.1	860.5	859.3	2.06	1.92		894.8				937.4	927.7	4.76	3.68
	isovaleraldehyde	912.8	919.1	908.1	0.69	-0.51		936.0				951.3	963.9	1.63	2.98
	2-methylbutanal	913.3	893.9	890.2	-2.12	-2.53		931.2				897.2	920.6	-3.65	-1.14
	valeraldehyde	953.8	966.8	959.3	1.36	0.58		998.1				1037.6	1007.9	3.96	0.98
	2-butenal	967.2	897.7	912.7	-7.19	-5.63		1061.5				953.8	955.2	-10.15	-10.01
	2-ethylbutyraldehyde	1009.6	1000.9	989.8	-0.86	-1.96		1018.0				1146.8	1112.5	12.65	9.28
	hexanal	1059.3	1113.6	1133.3	5.13	6.99		1098.3				1135.8	1156.0	3.41	5.25
	heptanal	1162.7	1149.4	1148.4	-1.14	-1.23		1199.6				1207.7	1176.9	0.68	-1.89
	octanal	1265.4	1240.9	1238.5	-1.94	-2.13		1298.8				1265.8	1249.2	-2.54	-3.82
Ⅱ	2-pentanone	973.9	979.3	978.7	0.55	0.49		996.2				1011.0	993.0	1.49	-0.32
	3-methyl-2-pentanone	1036.1	1023.7	1021.1	-1.20	-1.45		1033.9				1021.6	1008.8	-1.19	-2.43
	3-hexanone	1048.4	1043.9	1042.3	-0.43	-0.58		1068.0				1055.9	1058.4	-1.13	-0.90
	3-heptanone	1153.6	1132.8	1139.2	-1.80	-1.25		1167.2				1154.8	1158.0	-1.06	-0.79
	propanal	739.4	760.0	764.3	2.79	3.37		808.8				855.9	856.7	5.82	5.92
	trimethylacetaldehyde	841.6	876.4	900.8	4.13	7.03		822.6				779.7	840.5	-5.22	2.18
	3,3-dimethylbutanal	978.4	943.3	938.1	-3.59	-4.12		968.6				885.9	942.6	-8.54	-2.68
	2-ethylhexanal	1205.4	1109.1	1129.7	-7.99	-6.28		1197.8				1189.8	1240.2	-0.67	3.54

Table 1 Experimental[20] and predicted retention indices of the investigated aldehydes and ketones on two chromatographic columns

Group	Compound	RI of DB-210						RI of HP-Innowax
		Exp	Pred		RE/%			Pred	Pred	RE/%
		Exp	Ind	Ens	Ind	Ens	Ind	Pred	Ens	Ind	Ens
Ⅰ	acetone	792.9	764.8	792.9	-3.54	0.00		835.0				877.3	879.1	5.07	5.28
	2-butanone	882.1	869.9	872.6	-1.38	-1.08		919.8				917.5	915.6	-0.25	-0.46
	3-methyl-2-butanone	943.3	943.8	934.1	0.05	-0.98		949.4				951.8	948.4	0.25	-0.11
	3-pentanone	960.8	970.2	959.3	0.98	-0.16		996.9				972.3	968.0	-2.47	-2.90
	3,3-dimethyl-2-butanone	992.0	991.6	982.8	-0.04	-0.93		968.5				904.8	893.7	-6.58	-7.72
	4-methyl-2-pentanone	1027.1	1004.2	995.6	-2.23	-3.07		1025.2				1041.4	1033.6	1.58	0.82
	2,4-dimethyl-3-pentanone	1038.5	1084.2	1077.8	4.40	3.78		1014.8				971.1	1010.7	-4.31	-0.40
	2-hexanone	1081.5	1079.0	1075.6	-0.23	-0.55		1097.2				1100.2	1085.6	0.27	-1.06
	4-heptanone	1134.5	1126.9	1122.3	-0.67	-1.08		1139.4				1148.0	1156.6	0.75	1.51
	5-methyl-2-hexanone	1161.3	1122.9	1118.4	-3.31	-3.69		1156.1				1139.5	1148.8	-1.44	-0.63
	2-heptanone	1184.3	1186.6	1185.7	0.19	0.12		1195.8				1211.3	1183.5	1.30	-1.03
	2-methyl-3-heptanone	1192.4	1173.2	1164.1	-1.61	-2.37		1178.7				1201.5	1210.8	1.93	2.72
	5-methyl-3-heptanone	1026.9	1172.2	1184.1	14.15	15.31		1200.1				1166.2	1190.4	-2.82	-0.81
	3-octanone	1255.5	1252.3	1254.0	-0.25	-0.12		1265.5				1262.5	1257.1	-0.24	-0.66
	5-nonanone	1342.6	1310.0	1325.4	-2.43	-1.28		1334.1				1345.1	1361.4	0.82	2.05
	acrolein	743.7	770.1	776.1	3.55	4.36		867.0				853.0	855.0	-1.61	-1.38
	isobutanal	803.7	839.9	839.3	4.50	4.43		830.4				836.8	877.7	0.77	5.70
	butanal	843.1	860.5	859.3	2.06	1.92		894.8				937.4	927.7	4.76	3.68
	isovaleraldehyde	912.8	919.1	908.1	0.69	-0.51		936.0				951.3	963.9	1.63	2.98
	2-methylbutanal	913.3	893.9	890.2	-2.12	-2.53		931.2				897.2	920.6	-3.65	-1.14
	valeraldehyde	953.8	966.8	959.3	1.36	0.58		998.1				1037.6	1007.9	3.96	0.98
	2-butenal	967.2	897.7	912.7	-7.19	-5.63		1061.5				953.8	955.2	-10.15	-10.01
	2-ethylbutyraldehyde	1009.6	1000.9	989.8	-0.86	-1.96		1018.0				1146.8	1112.5	12.65	9.28
	hexanal	1059.3	1113.6	1133.3	5.13	6.99		1098.3				1135.8	1156.0	3.41	5.25
	heptanal	1162.7	1149.4	1148.4	-1.14	-1.23		1199.6				1207.7	1176.9	0.68	-1.89
	octanal	1265.4	1240.9	1238.5	-1.94	-2.13		1298.8				1265.8	1249.2	-2.54	-3.82
Ⅱ	2-pentanone	973.9	979.3	978.7	0.55	0.49		996.2				1011.0	993.0	1.49	-0.32
	3-methyl-2-pentanone	1036.1	1023.7	1021.1	-1.20	-1.45		1033.9				1021.6	1008.8	-1.19	-2.43
	3-hexanone	1048.4	1043.9	1042.3	-0.43	-0.58		1068.0				1055.9	1058.4	-1.13	-0.90
	3-heptanone	1153.6	1132.8	1139.2	-1.80	-1.25		1167.2				1154.8	1158.0	-1.06	-0.79
	propanal	739.4	760.0	764.3	2.79	3.37		808.8				855.9	856.7	5.82	5.92
	trimethylacetaldehyde	841.6	876.4	900.8	4.13	7.03		822.6				779.7	840.5	-5.22	2.18
	3,3-dimethylbutanal	978.4	943.3	938.1	-3.59	-4.12		968.6				885.9	942.6	-8.54	-2.68
	2-ethylhexanal	1205.4	1109.1	1129.7	-7.99	-6.28		1197.8				1189.8	1240.2	-0.67	3.54

Table 2 Statistics of the hologram quantitative structure-activity relationship (HQSAR) models with different fragment distinctions

Fragment distinction	DB-210				HP-Innowax
Fragment distinction	$q cv 2$	SEE	HL	PCs		SEE	HL	PCs
B	0.801	37.357	257	4	0.879	27.872	199	4
DA	0.913	21.6	97	5	0.909	24.377	151	6
A+DA	0.852	26.059	353	5	0.893	33.318	353	3
B+DA	0.804	34.375	257	4	0.859	47.967	151	2
A+C+DA	0.856	27.91	97	5	0.862	26.596	97	5
A+B+H+DA	0.821	24.813	353	5	0.883	26.959	257	4

Table 2 Statistics of the hologram quantitative structure-activity relationship (HQSAR) models with different fragment distinctions

Fragment distinction	DB-210				HP-Innowax
Fragment distinction	$q cv 2$	SEE	HL	PCs		SEE	HL	PCs
B	0.801	37.357	257	4	0.879	27.872	199	4
DA	0.913	21.6	97	5	0.909	24.377	151	6
A+DA	0.852	26.059	353	5	0.893	33.318	353	3
B+DA	0.804	34.375	257	4	0.859	47.967	151	2
A+C+DA	0.856	27.91	97	5	0.862	26.596	97	5
A+B+H+DA	0.821	24.813	353	5	0.883	26.959	257	4

Table 3 Statistics of the HQSAR models with different fragment sizes

DB-210						HP-Innowax
Fragment size	$q cv 2$	r²	SEE	HL	PCs	Fragment size		r²	SEE	HL	PCs
1月9日	0.935	0.99	17.124	151	5	4月7日	0.909	0.978	24.377	151	6
3月10日	0.921	0.99	17.71	151	5	1月9日	0.908	0.937	37.685	97	2
4月7日	0.913	0.984	21.6	97	5	3月10日	0.908	0.972	26.202	151	4
2月5日	0.897	0.955	36.017	151	4	3月6日	0.894	0.962	30.662	151	4

Table 3 Statistics of the HQSAR models with different fragment sizes

DB-210						HP-Innowax
Fragment size	$q cv 2$	r²	SEE	HL	PCs	Fragment size		r²	SEE	HL	PCs
1月9日	0.935	0.99	17.124	151	5	4月7日	0.909	0.978	24.377	151	6
3月10日	0.921	0.99	17.71	151	5	1月9日	0.908	0.937	37.685	97	2
4月7日	0.913	0.984	21.6	97	5	3月10日	0.908	0.972	26.202	151	4
2月5日	0.897	0.955	36.017	151	4	3月6日	0.894	0.962	30.662	151	4

Table 4 Statistics of individual and ensemble HQSAR models

Parameter	DB-210		HP-Innowax
Parameter	Individual model	Ensemble model	Individual model	Ensemble model
RMSE	39.123	40.417	41.451	37.553
MAPE	2.60%	2.69%	2.97%	2.74%
CCC	0.953	0.956	0.960	0.979
$q ext 2$	0.925	0.929	0.927	0.963
$Q F 2 2$	0.922	0.927	0.918	0.958
$Q F 3 2$	0.931	0.935	0.927	0.963
$q cv 2$	0.935	0.927	0.909	0.919

Table 4 Statistics of individual and ensemble HQSAR models

Parameter	DB-210		HP-Innowax
Parameter	Individual model	Ensemble model	Individual model	Ensemble model
RMSE	39.123	40.417	41.451	37.553
MAPE	2.60%	2.69%	2.97%	2.74%
CCC	0.953	0.956	0.960	0.979
$q ext 2$	0.925	0.929	0.927	0.963
$Q F 2 2$	0.922	0.927	0.918	0.958
$Q F 3 2$	0.931	0.935	0.927	0.963
$q cv 2$	0.935	0.927	0.909	0.919

References

[1]	Yu S, Yuan J, Zhang Y, et al. Future Med Chem, 2017,9(9):847
[2]	Jiao L, Zhang X, Qin Y, et al. Chemometr Intell Lab Syst, 2016,157:202
[3]	Jiao L, Wang Y, Qu L, et al. Colloid Surface A, 2020,586:124226
[4]	Xin M L, Chu Z H, Li Y. Chemical Journal of Chinese University, 2018,39(2):299
[4]	辛美玲, 褚振华, 李鱼. 高等学校化学学报, 2018,39(2):299
[5]	Gupta N, Vyas V, Patel B, et al. Med Chem Res, 2014,23(6):2757
[6]	Veríssimo G, Dutra E, Dias A, et al. J Mol Graph Model, 2019,90:180
[7]	Gadaleta D, Vuković K, Toma C, et al. J Cheminformatics, 2019,11(1):1
[8]	Li Y K, Shao X G, Cai W S. Chemical Journal of Chinese University, 2007,28(2):246
[8]	李艳坤, 邵学广, 蔡文生. 高等学校化学学报, 2007,28(2):246
[9]	Ouyang L, Zhou D, Ma Y, et al. Comput Ind Eng, 2018,123:242
[10]	Su Z, Tong W, Shi L, et al. Anal Lett, 2006,39(9):2073
[11]	Arodz T, Yuen D, Dudek A. J Chem Inf Model, 2006,46(1):416
[12]	Seierstad M, Agrafiotis D. Chem Biol Drug Des, 2006,67(4):284
[13]	Svetnik V, Wang T, Tong C, et al. J Chem Inf Model, 2005,45(3):786
[14]	Granitto P, Verdes P, Ceccatto H. Artif Intell, 2005,163(2):139
[15]	Jiao L, Wang Y, Tai W L, et al. Chinese Journal of Chromatography, 2020,38(5):600
[15]	焦龙, 王媛, 邰文亮, 等. 色谱, 2020,38(5):600
[16]	Liu H Y, Wang Z Y, Liu S S, et al. Chinese Journal of Chromatography, 2005,23(4):336
[16]	刘红艳, 王遵尧, 刘树深, 等. 色谱, 2005,23(4):336
[17]	Michotte Y, Massart D. J Pharm Sci-US, 2010,66(11):1630
[18]	Liao L M, Yang H, Lei G D. Computers and Applied Chemistry, 2016,33(12):1319
[18]	廖立敏, 杨欢, 雷光东. 计算机与应用化学, 2016,33(12):1319
[19]	Zhokhov A, Fomenko P, Aparkin A, et al. Russ J Phys Chem A+, 2015,89(1):125
[20]	Héberger K, Görgényi M. J Chromatogr A, 1999,845(1):21
[21]	Chirico N, Gramatica P. J Chem Inf Model, 2011,51(9):2320
[22]	Qin L T, Liu S S, Xiao Q F, et al. Environmental Chemistry, 2013,32(7):1208
[22]	覃礼堂, 刘树深, 肖乾芬, 等. 环境化学, 2013,32(7):1208
[23]	Tropsha A, Gramatica P, Gombar V. Mol Inform, 2003,22(1):69
[24]	Yang J W, Gu W W, Li Y. Bioscience Reports, 2019,39(5):1
[24]	杨家文, 顾文文, 李钰. 生物科学报告, 2019,39(5):1
[25]	Flower D. J Chem Inf Comp Sci, 1998,38(3):379
[26]	Punkvang A, Hannongbua S, Saparpakorn P, et al. J Biomol Struct Dyn, 2016,34(5):1079