Keywords: Polymer; Precatalyst preparation; Synchrocyclotron Radiations; Pyridine.

Editorial Article

In the current editorial, we study Adamantane, Irene, Naftazone and Pyridine– enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules (Figure 1) incorporation into the Nano Polymeric Matrix (NPM) by immersion of the Nano Polymeric Modified Electrode (NPME) as molecular enzymes and drug targets for human cancer cells, Tissues and tumors treatment under synchrotron and synchrocyclotron radiations. In this regard, the development of Chemical Modified Electrodes (CEMs) is at present an area of great interest. CEMs can be divided broadly into two main categories; namely, Surface modified and bulk modified electrodes. Methods of surface modification include adsorption, Covalent bonding, attachment of polymer Nano films, etc. Polymer Nano film coated electrodes can be differentiated from other modification methods such as adsorption and covalent bonding in that they usually involve multilayer as opposed to monolayer frequently encountered for the latter methods. The thicker Nano films imply more active sites which lead to larger analytical signals. This advantage coupled with other, Their versatility and wide applicability, Makes polymer Nano film modified electrodes particularly suitable for analytical applications [1-27].

Electrochemical polymerization offers the advantage of reproducible deposition in terms of Nano film thickness and loading, Making the immobilization procedure of a metal– based electrocatalyst very simple and reliable for Adamantane, Irene, Naftazone and Pyridine–enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules–encapsulating Carbon nanotubes incorporation into the Nano Polymeric Matrix (NPM) by immersion of the Nano Polymeric Modified Electrode (NPME) as molecular enzymes and drug targets for human cancer cells, Tissues and tumors treatment under synchrotron and synchrocyclotron radiations, Also it must be notice that the nature of working electrode substrate in electropreparation of polymeric Nano film is very important, Because properties of polymeric Nano films depend on the working electrode anti–cancer Nano materials. The ease and fast preparation and of obtaining a new reproducible surface, The low residual current, porous surface and low cost of Multi–Walled Carbon Nanotubes (MWCNTs) paste are some advantages of Carbon Paste Electrode (CPE) over all other solid electrodes [28-92].

On the other hand, it has been shown that, macrocyclic complexes of Adamantane, Irene, Naftazone and Pyridine– enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules–encapsulating Carbon nanotubes are interest as modifying agents because in basic media Adamantane, Irene, Naftazone and Pyridine–enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules–encapsulating Carbon nanotubes redox centers show high catalytic activity towards the oxidation of small organic anti–cancer Nano compounds. The high–valence species of Adamantane, Irene, Naftazone and Pyridine– enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules–encapsulating Carbon nanotubes seem to act as strong oxidizing agents for low–electroactivity organic substrates. 1,2–Dioxetane (1,2–Dioxacyclobutane), 1,3–Dioxetane (1,3–Dioxacyclobutane), DMDM Hydantoin and Sulphobe as the anti–cancer organic intermediate products of methanol oxidation as well as formic acid, is important to investigate its electrochemical oxidation behavior in Adamantane, Irene, Naftazone and Pyridine–enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules–encapsulating Carbon nanotubes incorporation into the Nano Polymeric Matrix (NPM) by immersion of the Nano Polymeric Modified Electrode (NPME) as molecular enzymes and drug targets for human cancer cells, Tissues and tumors treatment under synchrotron and synchrocyclotron radiations [93-110].

In this editorial, we decided to combine the above mentioned advantageous features for the aim of Adamantane, Irene, Naftazone and Pyridine–enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules– encapsulating Carbon nanotubes incorporation into the Nano Polymeric Matrix (NPM) by immersion of the Nano Polymeric Modified Electrode (NPME) as molecular enzymes and drug targets for human cancer cells, Tissues and tumors treatment under synchrotron and synchrocyclotron radiations. Furthermore, in this editorial, we prepared poly Nano films by electropolymerization at the surface of Multi–Walled Carbon Nanotubes (MWCNTs) paste electrode. Then, Adamantane, Irene, Naftazone and Pyridine–enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules–encapsulating Carbon nanotubes were incorporated into the Nano Polymeric Matrix (NPM) by immersion of the Nano Polymeric Modified Electrode (NPME) in a solution. The modifier layer of Adamantane, Irene, Naftazone and Pyridine–enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules– encapsulating Carbon nanotubes at the electrode surface acts as a Nano catalyst for the treatment of human cancer cells, tissues and tumors under synchrotron and synchrocyclotron radiations. Suitability of this Adamantane, Irene, Naftazone and Pyridine–enhanced precatalyst preparation stabilization and initiation (PEPPSI) Nano molecules–encapsulating Carbon nanotubes–modified polymeric Multi–Walled Carbon Nanotubes (MWCNTs) paste electrode toward the electrocatalytic treatment of human cancer cells, tissues and tumors under synchrotron and synchrocyclotron radiations in alkaline medium at ambient temperature was investigated [111-150].

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57. Heidari A. Chemotherapy a Last Resort for Cancer Treatment. Chemo Open Access. 2016; 5(4). doi: 10.4172/2167-7700.1000e130   
58. Heidari A. Separation and Pre–Concentration of Metal Cations–DNA/RNA Chelates Using Molecular Beam Mass Spectrometry with Tunable Vacuum Ultraviolet (VUV) Synchrotron Radiation and Various Analytical Methods. Mass Spectrom Purif Tech. 2016; 2(101). doi: 10.4172/2469-9861.1000e101   
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60. Heidari A. Cancer Risk Prediction and Assessment in Human Cells under Synchrotron Radiations Using Quantitative Structure Activity Relationship (QSAR) and Quantitative Structure Properties Relationship (QSPR) Studies. Int J Clin Med Imaging. 2016; 3(516).   
61. Heidari A. A Novel Approach to Biology. Electronic J Biol. 2016; 12(4).   
62. Heidari A. Innovative Biomedical Equipment's for Diagnosis and Treatment. J Bioengineer & Biomedical Sci. 2016; 6(2).   
63. Heidari A. Integrating Precision Cancer Medicine into Healthcare. Medicare Reimbursement Changes and the Practice of Oncology: Trends in Oncology Medicine and Practices. J Oncol Med & Pract. 2016; 1(2).   
64. Heidari A. Promoting Convergence in Biomedical and Biomaterials Sciences and Silk Proteins for Biomedical and Biomaterials Applications: An Introduction to Materials in Medicine and Bioengineering Perspectives. J Bioengineer & Biomedical Sci. 2016; 6(3). doi: 10.4172/2155- 9538.1000e126   
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66. Heidari A. Biomolecular Spectroscopy and Dynamics of Nano–Sized Molecules and Clusters as Cross–Linking–Induced Anti–Cancer and Immune–Oncology Nano Drugs Delivery in DNA/RNA of Human Cancer Cells' Membranes under Synchrotron Radiations: A Payload–Based Perspective. Arch Chem Res. 2017; 1(2). doi: 10.21767/2572-4657.100011   
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77. Heidari A. Nanomedicine–Based Combination Anti–Cancer Therapy between Nucleic Acids and Anti–Cancer Nano Drugs in Covalent Nano Drugs Delivery Systems for Selective Imaging and Treatment of Human Brain Tumors Using Hyaluronic Acid. Alguronic Acid and Sodium Hyaluronate as Anti–Cancer Nano Drugs and Nucleic Acids Delivery under Synchrotron Radiation. Am J Drug Deliv. 2017; 5(2). doi: 10.21767/2321-547X.1000016   
78. Heidari A. Clinical Trials of Dendritic Cell Therapies for Cancer Exposing Vulnerabilities in Human Cancer Cells' Metabolism and Metabolomics: New Discoveries. Unique Features Inform New Therapeutic Opportunities. Biotech's Bumpy Road to the Market and Elucidating the Biochemical Programs that Support Cancer Initiation and Progression. J Biol Med Science. 2017; 1(103).   
79. Heidari A. The Design Graphene–Based Nanosheets as a New Nanomaterial in Anti–Cancer Therapy and Delivery of Chemotherapeutics and Biological Nano Drugs for Liposomal Anti–Cancer Nano Drugs and Gene Delivery. Br Biomed Bull. 2017; 5(305). doi: 10.21767/2471-9897.1000305   
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81. Heidari A. Elimination of the Heavy Metals Toxicity and Diseases in Disruption of Extracellular Matrix (ECM) Proteins and Cell Adhesion Intelligent Nanomolecules Adjustment in Cancer Metastases Using Metalloenzymes and under Synchrotron Radiation. Lett Health Biol Sci. 2017; 2(2): 1-4. doi: 10.15436/2475-6245.17.019   
82. Heidari A. Treatment of Breast Cancer Brain Metastases through a Targeted Nanomolecule Drug Delivery System Based on Dopamine Functionalized Multi–Wall Carbon Nanotubes (MWCNTs) Coated with Nano Graphene Oxide (GO) and Protonated Polyaniline (PANI) in Situ During the Polymerization of Aniline Autogenic Nanoparticles for the Delivery of Anti–Cancer Nano Drugs under Synchrotron Radiation. Br J Res. 2017; 4(3): 16. doi: 10.21767/2394-3718.100016   
83. Heidari A. Sedative. Analgesic and Ultrasound–Mediated Gastrointestinal Nano Drugs Delivery for Gastrointestinal Endoscopic Procedure. Nano Drug–Induced Gastrointestinal Disorders and Nano Drug Treatment of Gastric Acidity. Res Rep Gastroenterol. 2017; 1(1).   
84. Heidari A. Synthesis, Pharmacokinetics, Pharmacodynamics, Dosing, Stability, Safety and Efficacy of Orphan Nano Drugs to Treat High Cholesterol and Related Conditions and to Prevent Cardiovascular Disease Under Synchrotron Radiation. J Pharm Sci Emerg Drugs. 2017; 5(1). doi: 10.4172/2380-9477.1000e104   
85. Heidari A. Non Linear Compact Proton Synchrotrons to Improve Human Cancer Cells and Tissues Treatments and Diagnostics through Particle Therapy Accelerators with Monochromatic Microbeams. J Cell Biol Mol Sci. 2017; 2(1): 1-5. doi: 10.15436/2471-5891.17.1631   
86. Heidari A. Design of Targeted Metal Chelation Therapeutics Nanocapsules as Colloidal Carriers and Blood–Brain Barrier (BBB) Translocation to Targeted Deliver Anti–Cancer Nano Drugs into the Human Brain to Treat Alzheimer's Disease under Synchrotron Radiation. J Nanotechnol Material Sci. 2017; 4(2): 1-5. doi: 10.15436/2377-1372.17.1591   
87. Gobato R, Heidari A. Calculations Using Quantum Chemistry for Inorganic Molecule Simulation BeLi2SeSi. Science Journal of Analytical Chemistry. 2017; 5(6): 76-85. doi: 10.11648/j.ajqcms.20170203.12   
88. Heidari A. Different High–Resolution Simulations of Medical. Medicinal. Clinical. Pharmaceutical and Therapeutics Oncology of Human Lung Cancer Translational Anti–Cancer Nano Drugs Delivery Treatment Process under Synchrotron and X–Ray Radiations. J Med Oncol. 2017; 1(1): 1.   
89. Heidari A. A Modern Ethnomedicinal Technique for Transformation. Prevention and Treatment of Human Malignant Gliomas Tumors into Human Benign Gliomas Tumors under Synchrotron Radiation. Am J Ethnomed. 2017; 4(1:10).   
90. Heidari A. Active Targeted Nanoparticles for Anti–Cancer Nano Drugs Delivery across the Blood–Brain Barrier for Human Brain Cancer Treatment. Multiple Sclerosis (MS) and Alzheimer's Diseases Using Chemical Modifications of Anti–Cancer Nano Drugs or Drug–Nanoparticles through Zika Virus (ZIKV) Nanocarriers under Synchrotron Radiation. J Med Chem Toxicol. 2017; 2(3): 1-5. 2017. doi: 10.15436/2575-808X.17.1594   
91. Heidari A. Investigation of Medical. Medicinal. Clinical and Pharmaceutical Applications of Estradiol. Mestranol (Norlutin). Norethindrone (NET). Norethisterone Acetate (NETA). Norethisterone Enanthate (NETE) and Testosterone Nanoparticles as Biological Imaging. Cell Labeling. Anti– Microbial Agents and Anti–Cancer Nano Drugs in Nanomedicines Based Drug Delivery Systems for Anti–Cancer Targeting and Treatment. Parana Journal of Science and Education (PJSE). 2017; 3(4): 10-19.   
92. Heidari A. A Comparative Computational and Experimental Study on Different Vibrational Biospectroscopy Methods. Techniques and Applications for Human Cancer Cells in Tumor Tissues Simulation. Modeling. Research. Diagnosis and Treatment. Open J Anal Bioanal Chem. 2017; 1(1): 014-020.   
93. Heidari A. Combination of DNA/RNA Ligands and Linear/Non–Linear Visible–Synchrotron Radiation–Driven N–Doped Ordered Mesoporous Cadmium Oxide (CdO) Nanoparticles Photocatalysts Channels Resulted in an Interesting Synergistic Effect Enhancing Catalytic Anti–Cancer Activity. Enz Eng. 2017; 6(1). doi: 10.4172/2329-6674.1000160   
94. Heidari A. Modern Approaches in Designing Ferritin. Ferritin Light Chain. Transferrin. Beta–2 Transferrin and Bacterioferritin–Based Anti–Cancer Nano Drugs Encapsulating Nanosphere as DNA–Binding Proteins from Starved Cells (DPS). Mod Appro Drug Des. 2017; 1(1): 000504. doi: 10.31031/MADD.2017.01.000504   
95. Heidari A. Potency of Human Interferon β–1a and Human Interferon β–1b in Enzymotherapy. Immunotherapy. Chemotherapy. Radiotherapy. Hormone Therapy and Targeted Therapy of Encephalomyelitis Disseminate/Multiple Sclerosis (MS) and Hepatitis A. B. C. D. E. F and G Virus Enter and Targets Liver Cells. J Proteomics Enzymol. 2017; 6(1). doi: 10.4172/2470-1289.1000e109   
96. Heidari A. Transport Therapeutic Active Targeting of Human Brain Tumors Enable Anti–Cancer Nanodrugs Delivery across the Blood–Brain Barrier (BBB) to Treat Brain Diseases Using Nanoparticles and Nanocarriers under Synchrotron Radiation. J Pharm Pharmaceutics. 2017; 4(2): 1-5. doi: 10.15436/2377-1313.17.034   
97. Heidari A, Brown C. Combinatorial Therapeutic Approaches to DNA/RNA and Benzylpenicillin (Penicillin G). Fluoxetine Hydrochloride (Prozac and Sarafem). Propofol (Diprivan). Acetylsalicylic Acid (ASA) (Aspirin). Naproxen Sodium (Aleve and Naprosyn) and Dextromethamphetamine Nanocapsules with Surface Conjugated DNA/RNA to Targeted Nano Drugs for Enhanced Anti–Cancer Efficacy and Targeted Cancer Therapy Using Nano Drugs Delivery Systems. Ann Adv Chem. 2017; 1(2): 061-069. doi: 10.29328/journal.aac.1001008   
98. Heidari A. High–Resolution Simulations of Human Brain Cancer Translational Nano Drugs Delivery Treatment Process under Synchrotron Radiation. J Transl Res. 2017; 1(1): 1-3.   
99. Heidari A. Investigation of Anti–Cancer Nano Drugs' Effects' Trend on Human Pancreas Cancer Cells and Tissues Prevention. Diagnosis and Treatment Process under Synchrotron and X–Ray Radiations with the Passage of Time Using Mathematica. Current Trends Anal Bioanal Chem. 2017; 1(1): 36-41.   
100. Heidari A. Pros and Cons Controversy on Molecular Imaging and Dynamics of Double–Standard DNA/RNA of Human Preserving Stem Cells–Binding Nano Molecules with Androgens/Anabolic Steroids (AAS) or Testosterone Derivatives through Tracking of Helium–4 Nucleus (Alpha Particle) Using Synchrotron Radiation. Arch Biotechnol Biomed. 2017; 1(1): 067-0100. doi: 10.29328/journal.hjb.1001007   
101. Heidari A. Visualizing Metabolic Changes in Probing Human Cancer Cells and Tissues Metabolism Using Vivo 1H or Proton NMR. 13C NMR. 15N NMR and 31P NMR Spectroscopy and Self–Organizing Maps under Synchrotron Radiation. SOJ Mater Sci Eng. 2017; 5(2): 1-6.   
102. Heidari A. Cavity Ring–Down Spectroscopy (CRDS). Circular Dichroism Spectroscopy. Cold Vapour Atomic Fluorescence Spectroscopy and Correlation Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Enliven: Challenges Cancer Detect Ther. 2017; 4(2): e001.   
103. Heidari A. Laser Spectroscopy. Laser–Induced Breakdown Spectroscopy and Laser–Induced Plasma Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Int J Hepatol Gastroenterol. 2017; 3(4): 079-084.   
104. Heidari A. Time–Resolved Spectroscopy and Time–Stretch Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Enliven: Pharmacovigilance and Drug Safety. 2017; 4(2): e001.   
105. Heidari A. Overview of the Role of Vitamins in Reducing Negative Effect of Decapeptyl (Triptorelin Acetate or Pamoate Salts) on Prostate Cancer Cells and Tissues in Prostate Cancer Treatment Process through Transformation of Malignant Prostate Tumors into Benign Prostate Tumors under Synchrotron Radiation. Open J Anal Bioanal Chem. 2017; 1(1): 021-026.   
106. Heidari A. Electron Phenomenological Spectroscopy. Electron Paramagnetic Resonance (EPR) Spectroscopy and Electron Spin Resonance (ESR) Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Austin J Anal Pharm Chem. 2017; 4(3): 1091.   
107. Heidari A. Therapeutic Nanomedicine Different High–Resolution Experimental Images and Computational Simulations for Human Brain Cancer Cells and Tissues Using Nanocarriers Deliver DNA/RNA to Brain Tumors under Synchrotron Radiation with the Passage of Time Using Mathematica and MATLAB. Madridge J Nano Tech. Sci. 2(2): 77-83.   
108. Heidari A. A Consensus and Prospective Study on Restoring Cadmium Oxide (CdO) Nanoparticles Sensitivity in Recurrent Ovarian Cancer by Extending the Cadmium Oxide (CdO) Nanoparticles–Free Interval Using Synchrotron Radiation Therapy as Antibody–Drug Conjugate for the Treatment of Limited–Stage Small Cell Diverse Epithelial Cancers. Cancer Clin Res Rep. 2017; 1(2): e001.   
109. Heidari A. A Novel and Modern Experimental Imaging and Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under White Synchrotron Radiation. Cancer Sci Res Open Access. 2017; 4(2): 1-8. doi: 10.15226/csroa.2017.00137   
110. Heidari A. Different High–Resolution Simulations of Medical. Medicinal. Clinical. Pharmaceutical and Therapeutics Oncology of Human Breast Cancer Translational Nano Drugs Delivery Treatment Process under Synchrotron and X–Ray Radiations. J Oral Cancer Res. 2017; 1(1): 12-17.   
111. Heidari A. Vibrational Decihertz (dHz). Centihertz (cHz). Millihertz (mHz). Microhertz (μHz). Nanohertz (nHz). Picohertz (pHz). Femtohertz (fHz). Attohertz (aHz). Zeptohertz (zHz) and Yoctohertz (yHz) Imaging and Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. International Journal of Biomedicine. 2017; 7(4). 335-340. doi: 10.21103/Article7(4)_IA1   
112. Heidari A. Force Spectroscopy and Fluorescence Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. EC Cancer. 2017; 2(5): 239-246.   
113. Heidari A. Photoacoustic Spectroscopy. Photoemission Spectroscopy and Photothermal Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. BAOJ Cancer Res Ther. 2017; 3(3): 045-052.   
114. Heidari A. J-Spectroscopy. Exchange Spectroscopy (EXSY). Nuclear Overhauser Effect Spectroscopy (NOESY) and Total Correlation Spectroscopy (TOCSY) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. EMS Eng Sci J. 2017; 1(2): 006-013.   
115. Heidari A. Neutron Spin Echo Spectroscopy and Spin Noise Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Int J Biopharm Sci. 2017; 1(1): 103-107. doi: 10.31021/ijbs.20181103   
116. Heidari A. Vibrational Decahertz (daHz). Hectohertz (hHz). Kilohertz (kHz). Megahertz (MHz). Gigahertz (GHz). Terahertz (THz). Petahertz (PHz). Exahertz (EHz). Zettahertz (ZHz) and Yottahertz (YHz) Imaging and Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Madridge J Anal Sci Instrum. 2017; 2(1): 41-46.   
117. Heidari A. Two-Dimensional Infrared Correlation Spectroscopy. Linear Two–Dimensional Infrared Spectroscopy and Non–Linear Two– Dimensional Infrared Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation with the Passage of Time. J Mater Sci Nanotechnol. 2018; 6(1): 101.   
118. Heidari A. Fourier Transform Infrared (FTIR) Spectroscopy. Near–Infrared Spectroscopy (NIRS) and Mid–Infrared Spectroscopy (MIRS) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation with the Passage of Time. Int J Nanotechnol Nanomed. 2018; 3(1): 1-6.   
119. Heidari A. Infrared Photo Dissociation Spectroscopy and Infrared Correlation Table Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation with the Passage of Time. Austin Pharmacol Pharm. 2018; 3(1): 1011.   
120. Heidari A. Novel and Transcendental Prevention. Diagnosis and Treatment Strategies for Investigation of Interaction among Human Blood Cancer Cells. Tissues. Tumors and Metastases with Synchrotron Radiation under Anti–Cancer Nano Drugs Delivery Efficacy Using MATLAB Modeling and Simulation. Madridge J Nov Drug Res. 2017; 1(1): 18-24.   
121. Heidari A. Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Open Access J Trans Med Res. 2018; 2(1): 00026-00032. doi: 10.15406/ oajtmr.2018.02.00026   
122. Gobato MRR, Gobato R, Heidari A. Planting of Jaboticaba Trees for Landscape Repair of Degraded Area. Landscape Architecture and Regional Planning. 2018; 3(1): 1-9. doi: 10.11648/j.larp.20180301.11   
123. Heidari A. Fluorescence Spectroscopy. Phosphorescence Spectroscopy and Luminescence Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation with the Passage of Time. SM J Clin. Med. Imaging. 2018; 4(1): 1018.   
124. Heidari A. Nuclear Inelastic Scattering Spectroscopy (NISS) and Nuclear Inelastic Absorption Spectroscopy (NIAS) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Int J Pharm Sci. 2018; 2(1): 1-14. doi: 10.19070/2332-2756- 180008e   
125. Heidari A. X–Ray Diffraction (XRD). Powder X–Ray Diffraction (PXRD) and Energy–Dispersive X–Ray Diffraction (EDXRD) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. J Oncol Res. 2018; 2(1): 1-14.   
126. Heidari A. Correlation Two–Dimensional Nuclear Magnetic Reso¬nance (NMR) (2D–NMR) (COSY) Imaging and Spectrosco¬py Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Arch Biotechnol Biomed. 2017; 1(1): 067-0100. doi: 10.29328/journal.hjb.1001007   
127. Heidari A. Thermal Spectroscopy. Photothermal Spectroscopy. Thermal Microspectroscopy. Photothermal Microspectroscopy. Thermal Macrospectroscopy and Photothermal Macrospectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. SM J Biometrics Biostat. 2018; 3(1): 1024.   
128. Heidari A. A Modern and Comprehensive Experimental Biospectroscopic Comparative Study on Human Common Cancers' Cells. Tissues and Tumors before and after Synchrotron Radiation Therapy. Open Acc J Oncol Med. 2018; 1(1).   
129. Heidari A. Heteronuclear Correlation Experiments such as Heteronuclear Single–Quantum Correlation Spectroscopy (HSQC). Heteronuclear Multiple–Quantum Correlation Spectroscopy (HMQC) and Heteronuclear Multiple–Bond Correlation Spectroscopy (HMBC) Comparative Study on Malignant and Benign Human Endocrinology and Thyroid Cancer Cells and Tissues under Synchrotron Radiation. J Endocrinol Thyroid Res. 2018; 3(1): 555603. doi: 10.19080/JETR.2018.03.555604   
130. Heidari A. Nuclear Resonance Vibrational Spectroscopy (NRVS). Nuclear Inelastic Scattering Spectroscopy (NISS). Nuclear Inelastic Absorption Spectroscopy (NIAS) and Nuclear Resonant Inelastic X–Ray Scattering Spectroscopy (NRIXSS) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Int J Bioorg Chem Mol Biol. 2018; 6(1e): 1-5. Doi: 10.19070/2332-2756-180008e   
131. Heidari A. A Novel and Modern Experimental Approach to Vibrational Circular Dichroism Spectroscopy and Video Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under White and Monochromatic Synchrotron Radiation. Glob J Endocrinol Metab. 2018; 1(3): 000514-000519.   
132. Heidari A. Pros and Cons Controversy on Heteronuclear Correlation Experiments such as Heteronuclear Single–Quantum Correlation Spectroscopy (HSQC). Heteronuclear Multiple–Quantum Correlation Spectroscopy (HMQC) and Heteronuclear Multiple–Bond Correlation Spectroscopy (HMBC) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. EMS Pharma J. 2018; 1(1): 002. doi: 10.19080/JETR.2018.03.555604   
133. Heidari A. A Modern Comparative and Comprehensive Experimental Biospectroscopic Study on Different Types of Infrared Spectroscopy of Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. J Analyt Molecul Tech. 2018; 3(1): 8.   
134. Heidari A. Investigation of Cancer Types Using Synchrotron Technology for Proton Beam Therapy: An Experimental Biospectroscopic Comparative Study. European Modern Studies Journal. 2018; 2(1): 13-29.   
135. Heidari A. Saturated Spectroscopy and Unsaturated Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Imaging J Clin Medical Sci. 2018; 5(1): 001-007. doi: 10.17352/2455-8702.000036   
136. A. Heidari. Small–Angle Neutron Scattering (SANS) and Wide–Angle X– Ray Diffraction (WAXD) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Int J Bioorg Chem Mol Biol. 2018; 6(2e): 1-6. doi: 10.19070/2332-2756-180009e   
137. Heidari A. Investigation of Bladder Cancer. Breast Cancer. Colorectal Cancer. Endometrial Cancer. Kidney Cancer. Leukemia. Liver. Lung Cancer. Melanoma. Non–Hodgkin Lymphoma. Pancreatic Cancer. Prostate Cancer. Thyroid Cancer and Non–Melanoma Skin Cancer Using Synchrotron Technology for Proton Beam Therapy: An Experimental Biospectroscopic Comparative Study. Ther Res Skin Dis. 2018; 1(1).   
138. Heidari A. Attenuated Total Reflectance Fourier Transform Infrared (ATR– FTIR) Spectroscopy. Micro–Attenuated Total Reflectance Fourier Transform Infrared (Micro–ATR–FTIR) Spectroscopy and Macro–Attenuated Total Reflectance Fourier Transform Infrared (Macro–ATR–FTIR) Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation with the Passage of Time. International Journal of Chemistry Papers. 2018; 2(1): 1-12. doi: 10.1021/la700713g   
139. Heidari A. Mössbauer Spectroscopy. Mössbauer Emission Spectroscopy and 57Fe Mössbauer Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Acta Scientific Cancer Biology. 2018; 2(3): 17-20. 2018.   
140. Heidari A. Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation with the Passage of Time. Organic & Medicinal Chem IJ. 2018; 6(1): 555676. doi: 10.15406/ oajtmr.2018.02.00026   
141. Heidari A. Correlation Spectroscopy. Exclusive Correlation Spectroscopy and Total Correlation Spectroscopy Comparative Study on Malignant and Benign Human AIDS–Related Cancers Cells and Tissues with the Passage of Time under Synchrotron Radiation. Int J Bioanal Biomed. 2018; 2(1): 001-007.   
142. Heidari A. Biomedical Instrumentation and Applications of Biospectroscopic Methods and Techniques in Malignant and Benign Human Cancer Cells and Tissues Studies under Synchrotron Radiation and Anti–Cancer Nano Drugs Delivery. Am J Nanotechnol Nanomed. 2018; 1(1): 001-009.   
143. Heidari A. Vivo 1H or Proton NMR. 13C NMR. 15N NMR and 31P NMR Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Ann Biomet Biostat. 2018; 1(1): 1001.   
144. Heidari A. Grazing–Incidence Small–Angle Neutron Scattering (GISANS) and Grazing–Incidence X–Ray Diffraction (GIXD) Comparative Study on Malignant and Benign Human Cancer Cells. Tissues and Tumors under Synchrotron Radiation. Ann Cardiovasc Surg. 2018; 1(2): 1006.   
145. Heidari A. Adsorption Isotherms and Kinetics of Multi–Walled Carbon Nanotubes (MWCNTs). Boron Nitride Nanotubes (BNNTs). Amorphous Boron Nitride Nanotubes (a–BNNTs) and Hexagonal Boron Nitride Nanotubes (h–BNNTs) for Eliminating Carcinoma. Sarcoma. Lymphoma. Leukemia. Germ Cell Tumor and Blastoma Cancer Cells and Tissues. Clin Med Rev Case Rep. 2018; 5(201). doi: 10.23937/2378-3656/1410201   
146. Heidari A. Correlation Spectroscopy (COSY). Exclusive Correlation Spectroscopy (ECOSY). Total Correlation Spectroscopy (TOCSY). Incredible Natural–Abundance Double–Quantum Transfer Experiment (INADEQUATE). Heteronuclear Single–Quantum Correlation Spectroscopy (HSQC). Heteronuclear Multiple–Bond Correlation Spectroscopy (HMBC). Nuclear Overhauser Effect Spectroscopy (NOESY) and Rotating Frame Nuclear Overhauser Effect Spectroscopy (ROESY) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Acta Scientific Pharmaceutical Sciences. 2018; 2(5): 30-35. doi: 10.19080/OMCIJ.2018.06.555695   
147. Heidari A. Small–Angle X–Ray Scattering (SAXS). Ultra–Small Angle X–Ray Scattering (USAXS). Fluctuation X–Ray Scattering (FXS). Wide–Angle X– Ray Scattering (WAXS). Grazing–Incidence Small–Angle X–Ray Scattering (GISAXS). Grazing–Incidence Wide–Angle X–Ray Scattering (GIWAXS). Small–Angle Neutron Scattering (SANS). Grazing–Incidence Small–Angle Neutron Scattering (GISANS). X–Ray Diffraction (XRD). Powder X–Ray Diffraction (PXRD). Wide–Angle X–Ray Diffraction (WAXD). Grazing– Incidence X–Ray Diffraction (GIXD) and Energy–Dispersive X–Ray Diffraction (EDXRD) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Oncol Res Rev. 2018; 1(1): 1-10. doi: 10.15761/ORR.1000104   
148. Heidari A. Pump–Probe Spectroscopy and Transient Grating Spectroscopy Comparative Study on Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Adv Material Sci Engg. 2018; 2 (1): 1-7.   
149. Heidari A. Grazing–Incidence Small–Angle X–Ray Scattering (GISAXS) and Grazing–Incidence Wide–Angle X–Ray Scattering (GIWAXS) Comparative Study on Malignant and Benign Human Cancer Cells and Tissues under Synchrotron Radiation. Insights Pharmacol Pharm Sci. 2018; 1(1): 1-8.   
150. Heidari A. Acoustic Spectroscopy. Acoustic Resonance Spectroscopy and Auger Spectroscopy Comparative Study on Anti–Cancer Nano Drugs Delivery in Malignant and Benign Human Cancer Cells and Tissues with the Passage of Time under Synchrotron Radiation. Nanosci Technol. 2018; 5(1): 1-9.