[1] K.Z. Alatawi, K.D. Albalawi, A.M. Aljuhani, N.D. Albalawi, A.I. Alalawy, A. A. Oyouni, Drug detection tests and the important factors and effects of the development of addiction, J. King Saud Univ. Sci. 34 (2022) 102093.
[2]
J.H. Khalsa,
G. Treisman,
E. McCance-Katz,
E. Tedaldi, Medical consequences of drug abuse and co-occurring infections: research at the National Institute on Drug Abuse, Nat. Lib. Med.,
29(3) (2008) 5–16.
[3]
A.M. Nawi,
R. Ismail,
F. Ibrahim,
M.R. Hassan,
M.R. Manaf,
N. Amit,
N. Ibrahim,
N.S. Shafurdin, Risk and protective factors of drug abuse among adolescents: Syst. Rev., 21(2021) 2088.
[4]C.T. Fakude, R.P. Modise, A.B. Haruna, J. Pillay, K.I. Ozoemena, Advances in the application of nanomaterials for the electrocatalytic detection of drugs of abuse, Adv. Energy Mater.,
2 (2023) 100056.
[5] A. A. Momoh, A. Alhassan, M.O. Ibrahim, S.A. Amoo, Curtailing the spread of drug-abuse and violence co-menace: An optimal control approach,
Alex. Eng. J., 61(6) (2022) 4399-4422.
[6] J.E. Henningfield, M.A. Coe, R.R. Griffiths, S.J. Belouin, A. Berger, A.R. Coker, S.D. Comer, D.J. Heal, P.S. Hendricks, C.D. Nichols, F. Sapienza, F.J. Vocci, F.Z. Zia, Psychedelic drug abuse potential assessment research for new drug applications and Controlled Substances Act scheduling, Neuropharmacology, 218 (2022) 109220.
[7] F.Baberi, D. Mirtorabi, S. Mahdavi, A. Hamedi, S. Hashemi Nazari, Spatial analysis of drug abuse mortality rates in Iran,
Tox. Analyt. Cliniq.,
35(4) (2023) 342-349
[8] J.S. Hägele, M.G. Schmid, Enantiomeric separation of Novel Psychoactive Substances by capillary electrophoresis using (+)‐18‐crown‐6‐tetracarboxylic acid as chiral selector, Chirality,
30(8) (2018) 1019-1026
[9] J.S. Hägele, M. Basrak, M.G. Schmid, Enantioselective separation of Novel Psychoactive Substances using a Lux. AMP 3 μm column and HPLC-UV,
J. Pharm. Biomed. Anal.,
179(5) (2020) 112967
[10] J. Czarny, J. Musiał, J.P. Czarny, N. Galant, M. Raczkowski, B. Buszewski, R. Gadzała-Kopciuch, Validation of a simple and quick method for determination of psychoactive substances, drugs and their metabolites from human blood by LC-MS/MS, Microchem. J.,
(2022)182 107922
[11] A.M. Al-Qaaneh, O.S. Al-Mohammadi, R.A. Musharraf, J.S. AlSaedi, J.L. Shaker, A.J. Aldhafiri, Prescription patterns of quetiapine for multiple drug abuse, depression, and psychosis: A retrospective study, Saudi Pharm. J., 31 (2023)101848
[12] B. Morentin, J.J. Meana, L.F. Callado, Ethanol and illicit drugs acute use and abuse as risk factors for suicide: A case–control study based on forensic autopsies in the Basque Country, Spain, Spanish J. Psychiatry and Mental Health, 16 (2023) 109–115
[13] O. Hope, O. Ness, J.G. Friesinger, A. Topor, T.D. Boe, Living needs a landscape: A qualitative study about the role of enabling landscapes for people with mental health and substance abuse problems, Health and Place, 84 (2023) 103144
[14] J.M. Marraffa, Drugs of abuse.
Encyclopedia of Toxicology, 3 (2024) 993-996.
[15] B.L.F. Kaplan, Immunotoxicology of Drugs of Abuse, Ref. Mod. Bio. Sci., (2024)
https://doi.org/10.1016/B978-0-323-95488-4.00051-6
[16] L. Saedi, Z. Rostami, B. Rabiei, N.O. Kattab, M. Volek, X. Hong, Identification of lomustine drug by graphyne-like, boron nitride: DFT approach, Molecular Physics,(2024)
https://doi.org/10.1080/00268976.2024.2318022
[17] H.R. Abd El-Mageed, M.A.A Ibrahim, Elucidating the adsorption and detection of amphetamine drug by pure and doped Al12N12, and Al12P12nano-cages, a DFT study, Mol. Phys.,
326 (2021) 115297
[18] X. Xu, W. Wang, J. Zhang, M. Derakhshandeh, Methylphenidate drug adsorption on the pristine magnesium oxide nanotubes; a computational study, Comput. Theor. Chem.,
1203 (2021) 113351
[19] K. Hyjek, G. Kurowski, K. Dymek, A. Boguszewska-Czubara, B. Budzynska, O. Wronikowska-Denysiuk, A. Gajda, W. Piskorz, P.Sliwa, M. Szumera, P. Jelen, M. Sitarz, P. J. Jodłowski, Metal-organic frameworks for efficient mephedrone detoxification or supervised withdrawal – synthesis, characterisation, and in vivo studies, J. Chem. Eng., 479 (2024) 147655
[20] K.M. Batoo, U.A. Hussein, A. Mohammed, A. Ibrahim, B. Zazoum, N. Jamil, N. Abdulhussein, M.F. Ramadan, U.K. Radi., A. A. Ami, S. J. Al-Shuwaili, A. Elawady , X. Hong, Evaluate the potential of BC3 nanosheet in the recognition Methamphetamine drug concentration in the human body: Insights from simulation in the field of medicine, Comput. Theor. Chem.,
1236 (2024) 114588
[23] F. Huang, M. Liu, M. Xie,
W. Liu, L. Sun, A combined study on the skeletal vibration of aminopyrine by terahertz time-domain spectroscopy and DFT simulation,
Optik.,
208 (2020) 163913
[24]Y. Zhang, Z. Zhang, M. A. Mustafa, S. K. Saraswat, Sh. M. Mekkey, L. Y. Qassem, M. M. Karim, A. H. Athab, Y. Elmasry, Application of biphenylene nanosheets for metronidazole detection,
J. Mol. Liq.,
398 (2024) 124216
[25]
S.J. Hoseyni,
A. Karbakhshzadeh,
A. Moshtaghi Zonouz,
B.Husseen, Computational investigation on interaction between graphene nanostructure BC3 and antiparkinson drug amantadine: Possible sensing study of BC3 and its doped derivatives on amantadine, Chem Rev Lett., (2024)
Articles in Press, 10.22034/CRL.2024.454413.1328
[29] J. Liu, Y. Xie, J. Ma, H. Chu, New Ca2+ based anticancer nanomaterials trigger multiple cell death targeting Ca2+ homeostasis for cancer therapy, Chem Biol Interact.,
393 (2024) 110948
[30]Pei, Y. Yan, S. Jayaraman, P. Rajagopal, P. Natarajan, V. Umapathy, S. Gopathy, Jeane Rebecca Roy h, J. Sadagopan, D. Thalamati i, Chella P. Palanisamy, M. Mironescu k, A review on advancements in the application of starch-based nanomaterials in biomedicine: Precision drug delivery and cancer therapy, Int. J. Biol. Macromol.,
265 (2024)1 130746
[31] X. Tu, H. Xu, C. Li, X. Liu, G. Fan, W. Sun, Adsorption performance of boron nitride nanomaterials as effective drug delivery carriers for anticancer drugs based on density functional theory, Comput. Theor. Chem.,
1203 (2021) 113360
[32] N. Beemkumar, M. Kaushik , A. Tripathi, M. Sharma, S. Khan, R. Sharma, Pluronic F127-chitosan modified magnesium oxide hybrid nanomaterials prepared via a one-pot method: Potential uses in antibacterial and anticancer agents, Surf. Interfaces,
42 (2023) 103327
[34] M. Afshar, R. Ranjineh Khojasteh, R. Ahmadi,M. N. Moghaddam,
In Silico Adsorption of Lomustin anticancer drug on the surface of Boron Nitride nanotube, Chem Rev Lett., 4(3) (2021) 178-184
[36] Z. Larian, M.H. Tabrizi, E.Karimi, N. Khatamian, G. Hosseini, H. Pourmahammadi, The folate-chitosan-decorated harmaline nanostructured lipid carrier (FCH-NLC), the efficient selective anticancer nano drug delivery system, J Drug Deliv Sci Technol.,
88 (2023) 104864
[37] P. R. Avula, A.K. Chettupalli, V. Chauhan, R.K. Jadi , Design, formulation, in-vitro and in-vivo pharmacokinetic evaluation of Nicardipine- nanostructured lipid carrier for transdermal drug delivery system, Mater. Today Chem., (2023)
In Press, Corrected Proof, https://doi.org/10.1016/j.matpr.2023.06.282
[38] S.Nurfadhlin, S. Ashari, J. Kit , N.K. Kassim, M. Hassan, N. Zainuddin, R. Mohamad, I. D. Azmi, Screening and selection of formulation components of nanostructured lipid carriers system for Mitragyna Speciosa (Korth). Havil drug delivery, Ind Crops Prod.,
198 (2023) 116668.
[42] A. Soltani, A.A. Peyghan, Z. Bagheri, H2O2 adsorption on the BN and SiC nanotubes: a DFT study, Physica E Low Dimens. Syst. Nanostruct., 48 (2013) 176–180
[43] J. Beheshtian, A.A. Peyghan, Z. Bagheri, Selective function of Al12N12 nano-cage towards NO and CO molecules, Comput. Mater. Sci., 62 (2012) 71–74
[44] J. Beheshtian, A.A. Peyghan, Z. Bagheri, M. Kamfiroozi, Interaction of small molecules (NO, H 2, N 2, and CH 4) with BN nanocluster surface, Struct. Chem., 23 (2012)1567–1572
[45] B. Adamowicz, W. Izydorczyk, J. Izydorczyk, A. Klimasek, W. Jakubik, J. Zywicki, ˙Response to oxygen and chemical properties of SnO2 thin-film gas sensors, Vacuum, 82 (2008) 966–970
[50] M. R. Jalali Sarvestani, S. Majedi,
A DFT study on the interaction of alprazolam with fullerene (C20), JCHEMLETT., 1(1) (2020) 32-38
[52] M.A. Shand, The chemistry and technology of magnesia, Wiley Online, Library (2006).
[53] M. Amft, N.V. Skorodumova, Catalytic activity of small MgO-supported Au clusters towards CO oxidation: a density functional study, Phys. Rev., 81 (2010) 195443
[54]. M. Wang, Y. Chen, W. Wang, T. Zhang, Adsorption of SO2 on pristine and defectivesingle-walled MgO nanotubes: a dispersion-corrected density-functional theory (DFT-D) study, Mater. Res., 8 (2021) 015023
[55] G. Xiao, R. Singh, A. Chaffee, P. Webley, Advanced adsorbents based on MgO andK2CO3 for capture of CO2 at elevated temperatures, Int. J. Greenhouse Gas Control, 5(4) (2011) 634-639
[56] M. Yang, C. Li, Y. Zhang, D. Jia, R. Li, Y. Hou, Predictive model for minimumchip thickness and size effect in single diamond grain grinding of zirconia ceramicsunder different lubricating conditions, Ceram. Int., 45 (2003)14908–14920
[57] W.A. Saunders, Structural dissimilarities between small II-VI compound clusters: MgO and CaO, Phys. Rev., 37 (1988) 6583–6586
[58] P.J. Ziemann, A. Castleman, Stabilities and structures of gas phase MgO clusters, J. Chem. Phys., 94 (1991) 718–728
[59] T. Gao, C. Li, D. Jia, Y. Zhang, M. Yang, Surface morphology assessment of CFRP transverse grinding using CNT nanofluid minimum quantity lubrication, J. Clean. Prod., 277 (2020) 123328
[60] M. J. Malliavin, C. Coudray, Ab initio calculations on (MgO) n,(CaO) n, and (NaCl) n clusters (n= 1–6), J. Chem. Phys., 106 (1997) 2323–2330
[61] B. Huang, L.I. Changhe, Y. Zhang, D. Wenfeng, Advances in fabrication of ceramic corundum abrasives based on sol–gel process, Chin. J. Aeronaut., 34 (2021) 1–17.
[62] R. Ma, Y. Bando, Uniform MgO nanobelts formed from in situ Mg3N2 precursor, Chem.Phys.Lett., 370 (2003)770–773
[63] Y. Yin, G. Zhang, Y. Xia, Synthesis and Characterization of MgO NanowiresThrough a Vapor-Phase Precursor Method, Adv. Funct. Mater., 12 (2002) 293–298
[64] A. Szabo, C. Perri, A. Csato, G. Giordano, D. Vuono, J.B. Nagy, Synthesis Methodsof Carbon Nanotubes and Related Materials, Mater., 3 (2010) 3092–3140
[65] C. Du, N. Pan, Preparation of single-walled carbon nanotube reinforced magnesiafilms, Nanotechnol., 15 (2004) 227–231
[66] Y.B. Li, Y. Bando, D. Golberg, Z.W. Liu, Ga-filled single-crystalline MgO nanotube: Wide-temperature range nanothermometer, Appl. Phys. Lett., 83 (2003) 999–1001
[67] J. Beheshtian, M.T. Baei, Z. Bagheri, A.A. Peyghan, Co-adsorption of CO moleculesat the open ends of MgO nanotubes, Struct. Chem., 23 (2012)1981–1986
[68] J. Beheshtian, A. Ahmadi Peyghan, Z. Bagheri, Ab initio study of NH3 and H2Oadsorption on pristine and Na-doped MgO nanotubes, Struct. Chem., 24 (2013)165–170
[69] R. Dong, X. Chen, X. Wang, W. Lu, Structural transition of hexagonal tube to rocksalt for (MgO)3n, 2≤n≤10, J. Chem. Phys., 129 (2008) 044705
[70] R. Valero, J.R.B. Gomes, D.G. Truhlar, F. Illas, Density functional study of CO andNO adsorption on Ni-doped MgO(100), J. Chem. Phys., 132 (2010) 104701
[71] J. Beheshtian, M. Kamfiroozi, Z. Bagheri, A. Ahmadi, Computational study of CO and NO adsorption on magnesium oxide nanotubes, Physica E-low-dimens. Syst. Nanostruct., 44 (2011) 546–549
[72] A. Ahmadi Peyghan, M.T. Baei, S. Hashemian, M. Moghimi, Adsorption of nitrous oxide on the (6,0) magnesium oxide nanotube, Chin. Chem. Lett., 23 (2012) 1275–1278
[73] H. Ammar, Adsorption of NO Molecule on Oxygen Vacancy-Defected MgO Nanotubes: DFT Study, Eur. J. Scientif. Res., 120 (2014) 401
[74] M. Schmidt, K. Baldridge, J. Boatz, S. Elbert, M. Gordon, J. Jenson, S. Koseki,N. Matsunaga, K. Nguyen, S.J. Su, T. Windus, M. Dupuis, J. Montgomery, Generalatomic and molecular electronic structure system, J. Comp. Chem., 14 (1993) 1347–1363
[75] N.M. O’Boyle, A.L. Tenderholt, K.M. Langner, cclib: a library for packageindependent computational chemistry algorithms, J. Comput. Chem., 29 (2008) 839–845
[76] S. Grimme, Accurate description of van der Waals complexes by density functional theory including empirical corrections, J. Comput. Chem., 25 (2004) 1463–1473
[77] J. Tao, J.P. Perdew, V.N. Staroverov, G.E. Scuseria, Climbing the Density Functional Ladder: Nonempirical Meta-Generalized Gradient Approximation Designed for Molecules and Solids, Phys. Rev. Lett., 91 (2003) 146401
[78] S.F. Boys, F. Bernardi, The calculation of small molecular interactions by the differences of separate total energies. Some procedures with reduced errors, Mol. Phys., 19 (1970) 553–566
[79] G. Ge, Q. Jing, Y. Luo, Density functional theory study on the structural and electronic properties of Ag-adsorbed (MgO) nanoclusters, Sci. China, Ser., 52 (2009) 734–741
[80] P. Wu, G. Cao, F. Tang, M. Huang, Electronic and magnetic properties of transition metal doped MgO sheet: A density-functional study, Comput. Mater. Sci., 86 (2014) 180–185
[81] B. Badhani, N. Sharma, R. Kakkar, Gallic acid: a versatile antioxidant with promising therapeutic and industrial applications, RSC Adv., 5 (2015) 27540–27557
[82] E.Vessally, P. Farajzadeh, E. Najafi, Possible Sensing Ability of Boron Nitride Nanosheet and its Al– and Si–Doped Derivatives for Methimazole drug by Computational Study. IJCCE, 40 (2021)
https://doi.org/.10.30492/ijcce.2021.141635.4498
[83] M. Nayebzadeh, A.A. Peyghan, H. Soleymanabadi, Density functional study on the adsorption and dissociation of nitroamine over the nanosized tube of MgO, Physica E Low Dimens. Syst. Nanostruct., 62 (2014) 48–54
[84] R. Kakkar, P.N. Kapoor, K.J. Klabunde, First Principles Density Functional Study of the Adsorption and Dissociation of Carbonyl Compounds on Magnesium Oxide Nanosurfaces, J. Phys. Chem., 110 (2006) 25941–25949
[85] R. Padash, M.R. Esfahani, A.S. Rad, The computational quantum mechanical study of sulfamide drug adsorption onto X12Y12 fullerene-like nanocages: detailed DFT and QTAIM investigations, J. Biomol. Struct. Dyn., DOI 10.1080/07391102.2020.1792991(2020) 1-11.
[86] A. Hosseinian, S. Soleimani-amiri, S. Arshadi, E. Vessally, L. Edjlali, Boosting the adsorption performance of BN nanosheet as an anode of Na-ion batteries: DFT studies, Phys. Lett., 381 (2017) 2010–2015.
[87] S. Sathyanarayanamoorthi, B. Suganthi, V. Kannappan, R. Kumar, Solubility study of cefpodoxime acid antibiotic in terms of free energy of solution - Insights from polarizable continuum model (PCM) analysis, J. Mol. Liq., 224 (2016) 657-661
[88] Y. Cao, Z. Rostami, R. Ahmadi, S.B. Azimi, M.M.R. Nayini, M.J. Ansari, M. Derakhshandeh, Study the role of MgONTs on adsorption and detection of carbon dioxide: First-principles density calculations, Comput. Theor. Chem., 1208 (2022) 113572
