What is he best known for?
The fields of study he is best known for:
- Organic chemistry
- Enzyme
- Catalysis
His main research concerns Stereochemistry, Crystallography, Ligand, Crystal structure and Copper.
His Stereochemistry research incorporates themes from Medicinal chemistry, Palladium, Chelation, DNA and Inosine.
His research in Crystallography intersects with topics in Coordination geometry, Imidazole, Deprotonation and Amide.
The various areas that Nick Hadjiliadis examines in his Ligand study include Oleic acid, Ionic bonding, Radical, Acetonitrile and Chemical synthesis.
His research integrates issues of Thioamide, Pyrene and Triethylamine in his study of Crystal structure.
His Copper research is multidisciplinary, incorporating perspectives in ATP7A, ATPase, Inorganic chemistry, Chaperone and Protein–protein interaction.
His most cited work include:
- Palladium coordination compounds as anti-viral, anti-fungal, anti-microbial and anti-tumor agents (337 citations)
- Antiproliferative and anti-tumor activity of organotin compounds (314 citations)
- The Atx1-Ccc2 complex is a metal-mediated protein-protein interaction. (170 citations)
What are the main themes of his work throughout his whole career to date?
Nick Hadjiliadis spends much of his time researching Stereochemistry, Crystallography, Medicinal chemistry, Crystal structure and Molecule.
The study incorporates disciplines such as Chelation, Ligand and Aqueous solution in addition to Stereochemistry.
His Crystallography study integrates concerns from other disciplines, such as Inorganic chemistry, Electron paramagnetic resonance, Metal and Amide.
His Inorganic chemistry research focuses on Copper and how it connects with Magnetic susceptibility.
His Medicinal chemistry research incorporates elements of Protonation, Acetonitrile, Palladium and Chloride.
His studies in Crystal structure integrate themes in fields like Thioamide, Hydrogen bond and Quinoxaline.
He most often published in these fields:
- Stereochemistry (52.38%)
- Crystallography (25.79%)
- Medicinal chemistry (23.81%)
What were the highlights of his more recent work (between 2007-2020)?
- Stereochemistry (52.38%)
- Medicinal chemistry (23.81%)
- Peptide (8.73%)
In recent papers he was focusing on the following fields of study:
Nick Hadjiliadis focuses on Stereochemistry, Medicinal chemistry, Peptide, Crystal structure and Ligand.
Nick Hadjiliadis has included themes like Crystallography, Electron paramagnetic resonance, Deprotonation and Amide in his Stereochemistry study.
His Crystallography research includes themes of Ionic bonding and Hydrochloride.
Nick Hadjiliadis combines subjects such as Benzothiazole, Phosphine, Acetonitrile and Antimony with his study of Medicinal chemistry.
His Crystal structure research includes elements of Enzyme, Catalysis and Potassium hydroxide.
His work carried out in the field of Ligand brings together such families of science as Hydroxybenzoic acid, Selenium and Pyrene.
Between 2007 and 2020, his most popular works were:
- Palladium coordination compounds as anti-viral, anti-fungal, anti-microbial and anti-tumor agents (337 citations)
- Antiproliferative and anti-tumor activity of organotin compounds (314 citations)
- Biological studies of new organotin(IV) complexes of thioamide ligands (103 citations)
In his most recent research, the most cited papers focused on:
- Organic chemistry
- Enzyme
- Catalysis
His primary areas of study are Stereochemistry, Medicinal chemistry, Antimony, Ligand and Organic chemistry.
The Stereochemistry study combines topics in areas such as Ionic bonding, Mössbauer spectroscopy, Crystal structure and Palladium.
His Crystal structure study incorporates themes from Potassium hydroxide, Hydroxybenzoic acid, Enzyme, Catalysis and Aqueous solution.
Nick Hadjiliadis interconnects Structure–activity relationship and Phosphine in the investigation of issues within Medicinal chemistry.
His research in Antimony tackles topics such as Biological activity which are related to areas like Quantitative structure–activity relationship and Antimony compounds.
His work on Iodide and Bioinorganic chemistry as part of general Organic chemistry research is frequently linked to Biological studies and Research groups, thereby connecting diverse disciplines of science.
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