This work is licensed under the Creative Commons Attribution 4.0 International License.
[1] Jiang, Z., Tian, Z., Zhang, C., Li, D., Wu, R., Tian, N., & Ma, L. (2022). Recent advances in speciation analyses of tobacco and other important economic crops. Current Analytical Chemistry, 18(5), 518-528.JiangZ.TianZ.ZhangC.LiD.WuR.TianN.MaL. (2022). Recent advances in speciation analyses of tobacco and other important economic crops. Current Analytical Chemistry, 18(5), 518-528.Search in Google Scholar
[2] Miao, H., Wang, Y., & Yang, X. (2018). Carbon dots derived from tobacco for visually distinguishing and detecting three kinds of tetracyclines. Nanoscale, 10(17), 8139-8145.MiaoH.WangY.YangX. (2018). Carbon dots derived from tobacco for visually distinguishing and detecting three kinds of tetracyclines. Nanoscale, 10(17), 8139-8145.Search in Google Scholar
[3] Fekhar, M., Daghbouche, Y., Bouzidi, N., & El Hattab, M. (2024). Rapid assessment of smokeless tobacco quality parameters using ATR-FT-MIR spectroscopy: Comparison of analytical/mathematical and machine learning approaches. Microchemical Journal, 201, 110670.FekharM.DaghboucheY.BouzidiN.El HattabM. (2024). Rapid assessment of smokeless tobacco quality parameters using ATR-FT-MIR spectroscopy: Comparison of analytical/mathematical and machine learning approaches. Microchemical Journal, 201, 110670.Search in Google Scholar
[4] Soon, J. M., & Abdul Wahab, I. R. (2022). A Bayesian approach to predict food fraud type and point of adulteration. Foods, 11(3), 328.SoonJ. M.Abdul WahabI. R. (2022). A Bayesian approach to predict food fraud type and point of adulteration. Foods, 11(3), 328.Search in Google Scholar
[5] Xiang, B., Cheng, C., Xia, J., Tang, L., Mu, J., & Bi, Y. (2020). Simultaneous identification of geographical origin and grade of flue-cured tobacco using NIR spectroscopy. Vibrational Spectroscopy, 111, 103182.XiangB.ChengC.XiaJ.TangL.MuJ.BiY. (2020). Simultaneous identification of geographical origin and grade of flue-cured tobacco using NIR spectroscopy. Vibrational Spectroscopy, 111, 103182.Search in Google Scholar
[6] Dsouza, R., & Bhojani, U. (2023). Strategic and contested use of food laws to ban smokeless tobacco products in India: a qualitative analysis of litigation. Tobacco control, 32(3), 275-279.DsouzaR.BhojaniU. (2023). Strategic and contested use of food laws to ban smokeless tobacco products in India: a qualitative analysis of litigation. Tobacco control, 32(3), 275-279.Search in Google Scholar
[7] Kumar, P., Rani, A., Singh, S., & Kumar, A. (2022). Recent advances on DNA and omics-based technology in Food testing and authentication: A review. Journal of Food Safety, 42(4), e12986.KumarP.RaniA.SinghS.KumarA. (2022). Recent advances on DNA and omics-based technology in Food testing and authentication: A review. Journal of Food Safety, 42(4), e12986.Search in Google Scholar
[8] Abdullava, F. S. (2020). LEGAL ISSUES OF PRODUCTION AND SALE OF TOBACCO PRODUCTS. In We speak English: legal, social, economic, political, cultural, educational, medical and technical issues (pp. 15-16).AbdullavaF. S. (2020). LEGAL ISSUES OF PRODUCTION AND SALE OF TOBACCO PRODUCTS. In We speak English: legal, social, economic, political, cultural, educational, medical and technical issues (pp. 15-16).Search in Google Scholar
[9] Alhazmi, H. A., Khalid, A., Sultana, S., Abdelwahab, S. I., Ahsan, W., Oraiby, M. E., & Bratty, M. A. (2019). Determination of phytocomponents of twenty-one varieties of smokeless tobacco using gas chromatography-mass spectroscopy (GC-MS). South African Journal of Chemistry, 72, 47-54.AlhazmiH. A.KhalidA.SultanaS.AbdelwahabS. I.AhsanW.OraibyM. E.BrattyM. A. (2019). Determination of phytocomponents of twenty-one varieties of smokeless tobacco using gas chromatography-mass spectroscopy (GC-MS). South African Journal of Chemistry, 72, 47-54.Search in Google Scholar
[10] Zhong, Y., Chen, Y., Hu, Y., Li, G., & Xiao, X. (2021). Multifunctional MgO/HKUST-1 composite for capture, catalysis, and cyclic cataluminescence detection of esters all-in-one to rapidly identify scented products. Analytical Chemistry, 93(48), 16203-16212.ZhongY.ChenY.HuY.LiG.XiaoX. (2021). Multifunctional MgO/HKUST-1 composite for capture, catalysis, and cyclic cataluminescence detection of esters all-in-one to rapidly identify scented products. Analytical Chemistry, 93(48), 16203-16212.Search in Google Scholar
[11] Adeniji, A., El-Hage, R., Brinkman, M. C., & El-Hellani, A. (2023). Nontargeted analysis in tobacco research: challenges and opportunities. Chemical Research in Toxicology, 36(11), 1656-1665.AdenijiA.El-HageR.BrinkmanM. C.El-HellaniA. (2023). Nontargeted analysis in tobacco research: challenges and opportunities. Chemical Research in Toxicology, 36(11), 1656-1665.Search in Google Scholar
[12] Staal, Y. C., van de Nobelen, S., Havermans, A., & Talhout, R. (2018). New tobacco and tobacco-related products: early detection of product development, marketing strategies, and consumer interest. JMIR Public Health and Surveillance, 4(2), e7359.StaalY. C.van de NobelenS.HavermansA.TalhoutR. (2018). New tobacco and tobacco-related products: early detection of product development, marketing strategies, and consumer interest. JMIR Public Health and Surveillance, 4(2), e7359.Search in Google Scholar
[13] Wang, X., Li, F., Wei, L., Huang, Y., Wen, X., Wang, D., & Fan, M. (2024). Rapid and Precise Differentiation and Authentication of Agricultural Products via Deep Learning-Assisted Multiplex SERS Fingerprinting. Analytical Chemistry, 96(11), 4682-4692.WangX.LiF.WeiL.HuangY.WenX.WangD.FanM. (2024). Rapid and Precise Differentiation and Authentication of Agricultural Products via Deep Learning-Assisted Multiplex SERS Fingerprinting. Analytical Chemistry, 96(11), 4682-4692.Search in Google Scholar
[14] Chao, M., Kai, C., & Zhiwei, Z. (2020). Research on tobacco foreign body detection device based on machine vision. Transactions of the Institute of Measurement and Control, 42(15), 2857-2871.ChaoM.KaiC.ZhiweiZ. (2020). Research on tobacco foreign body detection device based on machine vision. Transactions of the Institute of Measurement and Control, 42(15), 2857-2871.Search in Google Scholar
[15] O’Connor, R., Watson, C. H., Swan, G. E., Nettles, D. S., Geisler, R. C., & Hendershot, T. P. (2020). PhenX: agent measures for tobacco regulatory research. Tobacco control, 29(Suppl 1), s20–s26.O’ConnorR.WatsonC. H.SwanG. E.NettlesD. S.GeislerR. C.HendershotT. P. (2020). PhenX: agent measures for tobacco regulatory research. Tobacco control, 29(Suppl 1), s20-s26.Search in Google Scholar
[16] Wonjun Shin, Seongwoo Jang, Yunhyoung Hwang & Jihoon Han. (2024). Data-driven prediction of the mechanical behavior of nanocrystalline graphene using a deep convolutional neural network with PCA. Engineering with Computers(prepublish),1-18.ShinWonjunJangSeongwooHwangYunhyoungHanJihoon (2024). Data-driven prediction of the mechanical behavior of nanocrystalline graphene using a deep convolutional neural network with PCA. Engineering with Computers(prepublish),1-18.Search in Google Scholar
[17] Shyni H. Mary & E Chitra. (2024). PulmonU-Net: a semantic lung disease segmentation model leveraging the benefit of multiscale feature concatenation and leaky ReLU. Automatika(2),641-651.MaryShyni HChitraE (2024). PulmonU-Net: a semantic lung disease segmentation model leveraging the benefit of multiscale feature concatenation and leaky ReLU. Automatika(2),641-651.Search in Google Scholar
[18] Bin Wang, Fei Deng, Peifan Jiang, Shuang Wang, Xiao Han & Zhixuan Zhang. (2024). WiTUnet: A U-shaped architecture integrating CNN and Transformer for improved feature alignment and local information fusion. Scientific Reports(1),25525-25525.WangBinDengFeiJiangPeifanWangShuangHanXiaoZhangZhixuan (2024). WiTUnet: A U-shaped architecture integrating CNN and Transformer for improved feature alignment and local information fusion. Scientific Reports(1),25525-25525.Search in Google Scholar
