[1]. Tytarenko N., Kukuruza I., Zasadniuk O., Kostyuchenko A., Vozniuk A., Tactics of Treatment of Catastrophic Anti-Phospholipid Syndrome in Pregnant Woman: Based on a Clinical Case, Journal of Medicinal and Chemical Sciences, 2023, 6:2569 [Crossref], [Publisher] [2]. Ansari M., Zarei A., Moghaddam M.S.H., Shahlaei M., Moradi S., Ramazani A., Computational investigation on the potential inhibitory effect of fungal metabolites against viral RdRp of SARS-CoV-2 and HCV, Journal of Molecular Liquids, 2023, 390:123153 [Crossref], [Google Scholar], [Publisher] [3]. Edache E.I., Uzairu A., Mamza P.A., Adamu G., ylmethyl)-5-Oxo-2, 3-Dihydro-5H-Thiazolo [3, 2-a] Pyridine-3-Carboxamide, A Better Inhibitor of SARS-Cov-2 Spike Glycoprotein Than Some Standard Drugs: A Computational Prediction, Advanced Journal of Chemistry, Section A., 2023, 6:17 [Crossref], [Google Scholar], [Publisher] [4]. Zarei A., Amirkhani R., Golampour M., Tavakoli H., Ramazani A., Natural compounds as strong SARS-CoV-2 main protease inhibitors: computer-based study, Journal of Medicinal and Pharmaceutical Chemistry Research, 2023, 5:969 [Publisher] [5]. Kareem H., Jihad I., Hassan H., Znad M., Harbi M., Lahhob Q., Kadham M., Hamzah M., Jasim A., Biochemical and hematological variables in COVID-19 positive patients, Journal of Medicinal and Pharmaceutical Chemistry Research, 2023, 5:609 [Crossref], [Publisher] [6]. Ahmeid M.S., Essa S.B., Jasim E.R., Evaluating the level of vitamin D in Iraqi covid-19 patients and its association with biochemical parameters, Journal of Medicinal and Pharmaceutical Chemistry Research, 2023, 5:126 [Publisher] [7]. Roni M.A.H., Mortuza M.G., Rozina Shaha R.K., Hoque S., Kumer A., Identification of SARS-CoV-2 inhibitors from alkaloids using molecular modeling and in silico approaches, Journal of Medicinal and Nanomaterials Chemistry, 2023, 5:252 [Crossref], [Publisher] [8]. Amirkhani R., Zarei A., Gholampour M., Tavakoli H., Ramazani A., Honey and royal jelly natural products as possible antiviral nominations to combat SARS-CoV-2 main protease, Journal of Medicinal and Pharmaceutical Chemistry Research, 2022, 4:567 [Publisher] [9]. Mahkooyeh S., Eskandari S., Delavar E., Milanifard M., Mehni F., Chemical laboratory findings in children with covid-19: A systematic review and meta-analysis, Journal of Medicinal and Pharmaceutical Chemistry Research, 2022, 4:338 [Publisher] [10]. Asefy Z., Mammadova S., Nasibova A., Khalilov R., Aliyev E., Zhdanov R., Eftekhari A., Post corona: Chemicals, environmental factors, and public health, Journal of Medicinal and Pharmaceutical Chemistry Research, 2021, 3:526 [Publisher] [11]. Mohammadia S., Doustkhahc E., Chaleshtorid A.R.S., Esmailpourb M., Zamanie F., Esmailpoura A., A computational study at blocking probability of the SARS-CoV-2 spike protein through the binding of cellular receptors, Journal of Medicinal and Pharmaceutical Chemistry Research, 2021, 3:369 [Publisher] [12]. Javadi M., Numerical calculation of necessary distancing regarding SARS-CoV-2 (COVID-19) vs. spherical viruses, based on environmental features, Journal of Medicinal and Pharmaceutical Chemistry Research, 2021, 3:406 [Google Scholar], [Publisher] [13]. Shokrian N., Osquee H.O., ‎A Systematic Review Regarding the Diagnosis, Symptoms, and Methods of Home Quarantine in Children during Covid-19 Pandemic, Progress in Chemical and Biochemical Research, 2023, 6:88 [Crossref], [Publisher] [14]. Paritala V., Thummala H., Mohot T., Omicron B. 1.1. 529 tyrosine phosphatase receptor transition among SARS-CoV-2 heredities: a validation of homology modelling and phylogenetic analysis, Journal of Agricultural Sciences and Engineering, 2022, 4:71 [Publisher] [15]. Resen N.D., Gomaa E.A., Salem S.E., Abd El-Hady M.N., El-Defrawy A.M., Voltammetric Analysis of Lead Nitrate with Various Ligands in Aqueous Solutions at 302.15 K, Chemical Methodologies, 2023, 7:761 [Crossref], [Google Scholar], [Publisher] [16]. Ruiz Y., Carlos N., Musacchio A., Sanchez Y., Callard D., Perez R., Pojul M., Fuentes A., Single nucleotide polymorphism analysis and 3D protein models predict a gap between Bean golden yellow mosaic virus isolates found in Cuba and those of the continent, Journal of Agricultural Sciences and Engineering, 2022, 4:84 [Publisher] [17]. Edachea E.I., Dawia H.A., Ugbeb F.A., Dynamics Simulations and Structural Studies of Some Selected Inhibitors of the Glycoprotein (GPC) of Lassa Virus, Journal of Applied Organometallic Chemistry, 2023, 3:224 [Crossref], [Google Scholar], [Publisher] [18]. Baghernejad B., Alikhani M., Nano-cerium oxide/aluminum oxide as an efficient catalyst for the synthesis of xanthene derivatives as potential antiviral and anti-inflammatory agents, Journal of Applied Organometallic Chemistry, 2020, 2:140 [Crossref], [Google Scholar], [Publisher] [19]. Harismah K., Mirzaei M., Favipiravir: structural analysis and activity against COVID-19, Advanced Journal of Chemistry-Section B: Natural Products and Medical Chemistry, 2020, 2:55 [Crossref], [Google Scholar], [Publisher] [20]. Ara I., Maqbool M., Zehravi M., Gani I., Herbs Boosting Immunity in Covid-19: An Overview, Advanced Journal of Chemistry-Section B: Natural Products and Medical Chemistry, 2021, 3:289 [Crossref], [Google Scholar], [Publisher] [21]. Hosouna B., Malek H., Abdelsalam S., Ahwidy Z., Computational study of the effectiveness of natural herbal derivatives on COVID-19 virus, Advanced Journal of Chemistry-Section B: Natural Products and Medical Chemistry, 2021, 3:323 [Crossref], [Google Scholar], [Publisher] [23]. Saedi S., Saedi A., Ghaemi M.M., Fard M.M., Assessed the Complication of Central Nervous System in COVID‐19 Patients: A Systematic Review and Meta‐Analysis, Eurasian Journal of Science and Technology, 2022, 2:185 [Crossref], [Google Scholar], [Publisher] [24]. Motaharian E.S., Sadeghi Z., Mousavi L.S.S., Maleki R., Rigi Z., Fard M.M., Fard A.M.M., Nomiri F., A Systematic Review of the Literature, Management of Nursing Human Resources in Covid-19 Pandemics Period, Eurasian Journal of Science and Technology, 2022, 2:156 [Crossref], [Google Scholar], [Publisher] [25]. Saedi S., Saedi A., Ghaemi M.M., Fard M.M.,  A Review of Epidemiological Study of Covid-19 and Risk Factors, Eurasian Journal of Science and Technology, 2022, 2:230 [Crossref], [Google Scholar], [Publisher] [26]. Edache E.I., Uzairu A., Mamza P.A., Shallangwa G.A., Ibrahim M.T.,  Molecular Docking, Molecular Dynamics Simulation, and MM/GBSA Studies of (N-(4-Carbamoylphenyl)-8-cyclopropyl-7-(naphthalen-1-ylmethyl)-5-oxo-2,3-dihydro-[1,3]thiazolo[3,2-a]pyridine-3-carboxamide for Its Potential Use Against SARS-CoV-2, Journal of Applied Organometallic Chemistry, 2023, 3:321 [Crossref], [Google Scholar], [Publisher] [27]. Suárez D., Díaz N., SARS-CoV-2 main protease: A molecular dynamics study, Journal of Chemical Information and Modeling, 2020, 60:5815 [Crossref], [Google Scholar], [Publisher] [28]. Purwitasari N., Siswodihardjo S., Alhoot M.A., Agil M., Pharmacological Potential of Some Indonesian Medicinal Plants as Promising Options for COVID-19 During the Pandemic Era: A Literature Review, Journal of Medicinal and Chemical Sciences, 2023, 6:2735 [Crossref], [Google Scholar], [Publisher] [29]. Selmi A., Zarei A., Tachoua W., Puschmann H., Teymourinia H., Ramazani A., Synthesis and structural analysis of a novel stable quinoline dicarbamic acid: x-ray single crystal structure of (2-((4-((2-(carboxy (methyl) amino) ethoxy) carbonyl) quinoline-2-yl) oxy) ethyl)(methyl)-carbamic acid and molecular docking assessments to test its inhibitory potential against SARS-CoV-2 main protease, Chemical Methodologies, 2022, 6:463 [Crossref], [Google Scholar], [Publisher] [30]. Zarei A., Ramazani A., Rezaei A., Moradi S., Screening of honey bee pollen constituents against COVID-19: An emerging hot spot in targeting SARS-CoV-2-ACE-2 interaction, Natural Product Research, 2023, 37:974 [Crossref], [Google Scholar], [Publisher] [31]. Zhang G., Zhang A., Meng K., Zhang A., Dong S., Application of readily available metals for CH activation, Current Organic Chemistry, 2020, 24:1582 [Crossref], [Google Scholar], [Publisher] [32]. Angourani H.R., Zarei A., Moghadam M.M., Ramazani A., Mastinu A., Investigation on the Essential Oils of the Achillea Species: From Chemical Analysis to the In Silico Uptake against SARS-CoV-2 Main Protease, Life, 2023, 13:378 [Crossref], [Google Scholar], [Publisher] [33]. Al-Qaraghuli N., Zahid I., Study of Effects and Complications for People Infected with COVID-19, Journal of Medicinal and Chemical Sciences, 2023, 6:1137 [Crossref], [Google Scholar], [Publisher] [34]. Sahraeai, R., Hooshmand F., Ghaedi M., Safa S., Eftekharian F., Farrokhi S.,  Vitamin D in Mild to Moderate COVID-19: A Retrospective Cross-Sectional Study, Journal of Medicinal and Chemical Sciences, 2023, 6:55 [Crossref], [Publisher] [35]. Haghbeen M., Hakimelahi H., Tafvizi M., Hatami N., Kalani N., Dezhkam L., Moral Distress, COVID-19, and Healthcare Workers, a Systematic Review and Meta-Synthesis: Solutions by JUMS Clinical Decision-Making Scheme, Journal of Medicinal and Chemical Sciences, 2023, 6:71 [Crossref], [Google Scholar], [Publisher] [36]. Esfahani M., Aski B., Anari A., Gharehbaghi G., Sakhaei M., Shorafa E., Hooman N., Extreme Hypertension Associated with SARS-COVID-19 Infection in Pediatrics with Kidney Disease: A Retrospective Observational Study, Journal of Medicinal and Chemical Sciences, 2023, 6:79 [Crossref], [Google Scholar], [Publisher] [37]. Rajabbeigi E., Change of Essential Oil Composition of Parsley in Response to Static Magnetic Field, International Journal of Advanced Biological and Biomedical Research, 2022, 10:271 [Crossref], [Google Scholar], [Publisher] Salehi Sardoei A., Review on Iranian medicinal plants with anticancer properties, International Journal of Advanced Biological and Biomedical Research, 2022, 10:44 [Crossref], [Google Scholar], [Publisher] [39]. Vaeli N., Laboratory Study of Effective Factors on How to Extract Carvacrol from Oliveria Decumbens Plant with the Help of Supercritical Fluid CO2 and Using Ultrasound Waves, Eurasian Journal of Science and Technology, 2022, 2:32 [Crossref], [Google Scholar], [Publisher] [40]. Puri J.B., Shaikh A.M., Dhuldhaj U.P., Phytochemical and Biochemical Analysis of Ajwain Seed’s Content, Eurasian Journal of Science and Technology, 2024, 4:31 [Crossref], [Google Scholar], [Publisher] [41]. Igboecheonwu I., Garba Z.N., Nuh A.A., Comparative Analysis of Proximate and Mineral Compositions of Jatropha tanjorensis L. and Telfairia occidentalis Hook F. Leaves Cultivated in Zaria, Advanced Journal of Chemistry-Section B: Natural Products and Medical Chemistry, 2023, 5:17 [Crossref], [Publisher] [42].              Sikkander A.M., Bassyouni F., Yasmeen K., Mishra S.R., Lakshmi V., Synthesis of Zinc Oxide and Lead Nitrate Nanoparticles and their Applications: Comparative Studies of Bacterial and Fungal (E. coli, A. Niger), Journal of Applied Organometallic Chemistry, 2023, 3:255 [Crossref], [Publisher] [43]. Korbag S., Korbag I., A Short Review on Effects of Bisphenol A and Its Analogues on Endocrine System, Journal of Chemical Reviews, 2023, 5:380 [Crossref], [Google Scholar], [Publisher] [44]. Bako B., Danladi A.H., Bulus G.G., Shinggu J.P., A Comprehensive Review of Solvent-Induced Variability in Antioxidant Profiling of Plants Extract: Justicia secunda, Progress in Chemical and Biochemical Research, 2023, 1 [Crossref], [Publisher] [45]. Choudhary S., Malik Y.S., Tomar S., Identification of SARS-CoV-2 cell entry inhibitors by drug repurposing using in silico structure-based virtual screening approach, Frontiers in Immunology, 2020, 11:1664 [Crossref], [Google Scholar], [Publisher] [46]. Mengist H.M., Dilnessa T., Jin T., Structural basis of potential inhibitors targeting SARS-CoV-2 main protease, Frontiers in Chemistry, 2021, 9:622898 [Crossref], [Google Scholar], [Publisher] [47]. Singh A.K., Singh A., Singh R., Misra A., An updated practical guideline on use of molnupiravir and comparison with agents having emergency use authorization for treatment of COVID-19, Diabetes & Metabolic Syndrome: Clinical Research & Reviews, 2022, 16:102396 [Crossref], [Google Scholar], [Publisher] [48]. Stephenson J., FDA Authorizes Pharmacists to Prescribe Oral Antiviral Medication for COVID-19, in JAMA Health Forum, 2022, e222968 [Crossref], [Google Scholar], [Publisher] [49]. Saravolatz L.D., Depcinski S., Sharma M., Molnupiravir and nirmatrelvir-ritonavir: oral coronavirus disease 2019 antiviral drugs, Clinical Infectious Diseases, 2023, 76:165 [Crossref], [Google Scholar], [Publisher] [50]. Shivshankar P., Karmouty-Quintana H., Mills T., Doursout M.F., Wang Y., Czopik A.K., Evans S.E., Eltzschig H.K., Yuan X., SARS-CoV-2 infection: host response, immunity, and therapeutic targets, Inflammation, 2022, 45:1430 [Crossref], [Google Scholar], [Publisher] [51]. Khan M.T., Ali A., Wang Q., Irfan M., Khan A., Zeb M.T., Zhang Y.J., Chinnasamy S., Wei D.Q., Marine natural compounds as potents inhibitors against the main protease of SARS-CoV-2—a molecular dynamic study, Journal of Biomolecular Structure and Dynamics, 2021, 39:3627 [Crossref], [Google Scholar], [Publisher] [52]. Corona A., Wycisk K., Talarico C., Manelfi C., Milia J., Cannalire R., Esposito F., Gribbon P., Zaliani A., Iaconis D., Natural compounds inhibit SARS-CoV-2 nsp13 unwinding and ATPase enzyme activities, ACS Pharmacology & Translational Science, 2022, 5:226 [Crossref], [Google Scholar], [Publisher] [53]. Ngo S.T., Quynh Anh Pham N., Thi Le L., Pham D.-H., Vu, V.V., Computational determination of potential inhibitors of SARS-CoV-2 main protease, Journal of Chemical Information and Modeling, 2020, 60:5771 [Crossref], [Google Scholar], [Publisher] [54]. Ahmadi F.I., Fathollahi R., Dastan D., Phytochemical constituents and biological properties of Scutellaria condensata subsp. pycnotricha, Journal of Applied Organometallic Chemistry, 2020, 8:201 [Crossref], [Google Scholar], [Publisher] [55]. Thakur M., Nanda V., Composition and functionality of bee pollen: A review, Trends in Food Science & Technology, 2020, 98:82 [Crossref], [Google Scholar], [Publisher] [56]. Rosidi A., Khomsan A., Setiawan B., Riyadi H., Briawan D., Antioxidant potential of temulawak (Curcuma xanthorrhiza Roxb), Pakistan Journal of Nutrition, 2016, 15:556 [Crossref], [Google Scholar], [Publisher] [57]. Kirchdoerfer, R.N., Wang, N., Pallesen, J., Turner, H.L., Cottrell, C.A., McLellan, J.S., Ward, A.B. SARS Spike Glycoprotein - human ACE2 complex, Stabilized variant, all ACE2-bound particles. 2020 [Crossref], [Publisher] [58]. Morris G.M., Huey R., Lindstrom W., Sanner M.F., Belew R.K., Goodsell D.S., Olson A.J., AutoDock4 and AutoDockTools4: Automated docking with selective receptor flexibility, Journal of Computational Chemistry, 2009, 30:2785 [Crossref], [Google Scholar], [Publisher] [59]. Wan Y., Shang J., Graham R., Baric R.S., Li F., Receptor recognition by the novel coronavirus from Wuhan: an analysis based on decade-long structural studies of SARS coronavirus, Journal of Virology, 2020, 94:10.1128/jvi. 00127 [Crossref], [Google Scholar], [Publisher] [61]. Ferreira J.C., Rabeh W.M., Biochemical and biophysical characterization of the main protease, 3-chymotrypsin-like protease (3CLpro) from the novel coronavirus SARS-CoV2, Scientific Reports, 2020, 10:22200 [Crossref], [Google Scholar], [Publisher]