Molecular Modeling – STEM Skills Lab

Nucleic Acids Modeling and Simulations

Stem Skills Lab — Mon, 02 Jan 2023 06:57:51 +0000

Studying Nucleic acid modeling and simulations is essential for understanding the structure and function of DNA and RNA, which are critical biomolecules involved in many crucial biological processes. In addition, nucleic acid modeling and simulations study can provide students with several benefits, including:

Improved understanding of biological processes: By studying nucleic acid modeling and simulations, students can gain a deeper understanding of how DNA and RNA function at the molecular level and how they are involved in various biological processes, such as gene expression and regulation.
Practical skills in computational biology: Nucleic acid modeling and simulations require specialized software and computational techniques, which can help students develop practical skills in computational biology. These skills are in high demand in academia and industry.
Opportunities for interdisciplinary research: Nucleic acid modeling and simulations involve integrating concepts and techniques from multiple disciplines, such as chemistry, biology, and computer science. This multidisciplinary nature can allow students to collaborate on research projects with researchers from different fields.
Career opportunities: The demand for skilled professionals in nucleic acid modeling and simulations is growing as these techniques are increasingly used to study a wide range of biological problems. As such, students who study nucleic acid modeling and simulations may have good job prospects in academia, industry, and government research organizations.

Studying nucleic acid modeling and simulations can give students a deeper understanding of biological processes, practical skills in computational biology, opportunities for interdisciplinary research, and good career prospects.

Module – 6 months

Nucleic Acids MODELING & SIMULATION

Topics

– Protein Data Bank (PDB), Nucleic Acid Data Bank (NDB) RCSB, UNIPROT

-Introduction to various sequence Databases

– Studying Sequence and 2D and 3D structure of DNA/RNA

-Learning Visualization tools (Rasmol and Pymol)

-Studying Various Motifs in RNA structures

– Analyzing H-bonding and Stacking between Nucleobases in RNA

– Modeling 3D structure of DNA/RNA

– Molecular Dynamics Simulations

– Simulation using GROMACS

-Analyzing Results

– Writing Report

Who can apply:

B.Tech. in (Biotechnology/ Industrial Biotechnology/ Bioinformatics/Material Sciences/Computer Sciences)
M.Sc. in (Biotechnology/Microbiology/Chemistry/Biochemistry/Bioinformatics/Life sciences/Material Sciences)
M.Tech. in (Biotechnology/Bioinformatics/ Industrial Biotechnology/Computer Sciences)
B.Pharmacy/ M.Pharmacy

Functional Material Simulations

Er. Kanav Kalra — Fri, 30 Dec 2022 16:22:56 +0000

Functional material simulations refer to the use of computer modeling and simulation techniques to study the properties and behaviors of functional materials. These materials are substances that have specific functions or properties that make them useful in various applications, such as electronics, energy storage, and structural materials.

Functional material simulations allow researchers and engineers to predict and understand the behavior of these materials under various conditions, such as temperature, pressure, and applied fields. This can help in the design and optimization of materials for specific applications, as well as in the development of new materials with improved properties.

There are several different techniques that can be used in functional material simulations, including density functional theory (DFT), molecular dynamics (MD), and Monte Carlo methods. These techniques can be used to simulate a wide range of materials, including metals, semiconductors, insulators, and polymers.

Overall, functional material simulations are an important tool in designing and developing functional materials, helping researchers and engineers to predict and understand the behavior of these materials and optimize their properties for specific applications.

Module 1 (6 months)

Modeling Thermoelectric Materials

Topics and Software

-Introduction to various crystal structure databases for materials

– Structure buildup using VESTA and XCrysden tools

– Studying optimization methodologies for structure minimization

-Prediction of Electronic Properties for a chosen material

-Confirming its stability using Phonon Calculations

-Prediction of Electronic Transport Properties using electronic Boltzmann Transport Equations

-Prediction of Phonon Transport properties using phononic Boltzmann Transport Equations

-Quantification of Material Thermoelectric Efficiency

-Analysis of the results

-Report writing

Tools Used: Quantum Espresso, Boltztrap1/2, ShengBTE

Visualization Tools: VESTA, XCrysden tools

Data Plotting: Gnuplot, Xmgrace

Module 2 (6 months)

Modeling Materials for Catalytic Applications

Topics and Software

– Introduction to various crystal structure databases for materials

– Structure buildup using VESTA and XCrysden tools

– Modeling of specific surface of the Bulk Material

– Studying optimization methodologies for structure minimization

– Prediction of Electronic Properties for a chosen material

– Confirming its stability using Phonon Calculations

– Screening of various reaction pathways on material surface

-Analysis of the results

-Report writing

Tools Used: Quantum Espresso, Siesta

Visualization Tools: VESTA, XCrysden tools

Data Plotting: Gnuplot, Xmgrace

Who can apply for Training?

B.Tech. in (Biotechnology/ Industrial Biotechnology/ Bioinformatics/Material Sciences/Computer Sciences)

M.Sc. in (Biotechnology/Microbiology/Chemistry/Biochemistry/Bioinformatics/Life sciences/Material Sciences)

M.Tech. in (Biotechnology/Bioinformatics/ Industrial Biotechnology/Computer Sciences)

B. Pharmacy/M.Pharmacy

Computational Design of Biosensors

Er. Kanav Kalra — Fri, 30 Dec 2022 16:21:32 +0000

Computational design of biosensors refers to using computer simulations and modeling techniques to design and optimize the performance of biosensors. Biosensors are devices that use living cells or biomolecules to detect and measure specific environmental substances or conditions.

In the industrial setting, the computational design of biosensors can be used to optimize the sensitivity, selectivity, and stability of these devices, as well as to predict their performance under various operating conditions. This can help develop biosensors with improved accuracy and reliability, which are critical for applications such as environmental monitoring, food safety, and medical diagnosis.

In addition to its industrial applications, the computational design of biosensors also has significant benefits for researchers. By using computational techniques to design and optimize biosensors, researchers can better understand the underlying biological processes involved in their operation and identify new opportunities for improving their performance. This can help develop more effective biosensors for a wide range of applications.

Module – 6 months

Modeling Biosensor/Chemosensor

Topics and Sofware

– Introduction to various crystal structure databases for materials

– Structure buildup using VESTA and XCrysden tools

– Building model for analyte (for example, gas, drug, ligands) to be sensed

– Probing the minimized structure of material-ligand complex

– Conformational searching of ligand on Biosensor/Chemosensor material surface

– Studying optimization methodologies for structure minimization

– Studying physical/chemical properties (for example Adsorption energy)

– Calculation of Density of States and other relevant properties

-Analysis of results

-Report writing

Tools Used: Quantum Espresso, Siesta

Visualization Tools: VESTA, XCrysden tools

Data Plotting: Gnuplot, Xmgrace

Who can apply for Training?

B.Tech. in (Biotechnology/ Industrial Biotechnology/ Bioinformatics/Material Sciences/Computer Sciences)

M.Sc. in (Biotechnology/Microbiology/Chemistry/Biochemistry/Bioinformatics/Life sciences/Material Sciences)

M.Tech. in (Biotechnology/Bioinformatics/ Industrial Biotechnology/Computer Sciences)

B. Pharmacy/M.Pharmacy

BIOMOLECULAR MODELING AND SIMULATIONS

Stem Skills Lab — Sun, 11 Dec 2022 03:50:33 +0000

Module – 6 months

Biomolecular Modelling and Docking

Topics

– Protein Data Bank (PDB), RCSB, UNIPROT
– Studying Sequence, 2D, and 3D structure.-Learning Visualization tools (Rasmol and Pymol)
-Studying Receptor and ligand structure
– Learning Docking methods
– Hands-on training of Autodock and Haddock tool-Analyzing Interactions between Ligand-Receptor Docked structure
– Molecular Dynamics Simulations
– Simulation using GROMACS-Analyzing Results

Who can Apply for training?

B.Tech. in (Biotechnology/ Industrial Biotechnology/ Bioinformatics/Material Sciences/Computer Sciences)
M.Sc. in (Biotechnology/Microbiology/Chemistry/Biochemistry/Bioinformatics/Life sciences/Material Sciences)
M.Tech. in (Biotechnology/Bioinformatics/ Industrial Biotechnology/Computer Sciences)
B.Pharmacy/ M.Pharmacy

Molecular Modeling and Drug Designing

Dr. Abdul Rajjak Shaikh — Tue, 08 Feb 2022 12:29:52 +0000

Molecular modeling and drug design is a field of study involving computational methods and technologies to identify and develop new drugs that can be used to treat various diseases. This course can provide several benefits to students, including:

– An in-depth understanding of molecular modeling and drug design principles and techniques, which can be helpful in various fields, including pharmaceutical research and development, biotechnology, and academic research.

– Exposure to cutting-edge computational tools and techniques that can predict the structures and functions of proteins and small molecules and evaluate their potential as drug candidates.

– An opportunity to conduct original research that contributes to molecular modeling and drug design and develop the skills and knowledge needed to pursue a career in this field.

– The ability to apply computational approaches to solve real-world biological problems and gain insights into diseases’ molecular basis and the mechanisms of drug action.

Overall, this course can provide students with a comprehensive understanding of the principles and applications of this field and can equip them with the skills and knowledge needed to pursue a successful career in this exciting and rapidly-growing area of science.

Module – I (2 months)	Ligand based drug design (Pharmacophore design)
Topics	-Introduction and Background -Understanding different file formats (sdf,mol2,pdb) -SMILES/canSMILE -Collection of primary key data -Pharmacophore preparation -Chemical Library preparation based on Pharmacophore -Insilico Screening (ADME) -Toxicity screening – QSAR(Quantitative structure-activity relationship) Databases – Pubchem, Drugbank, ZincPharmar etc -Tools – OpenBabel, Discovery Studio, KNIME, Marvin Sketch, and others (suggestions) etc
Module – II (4 months)	Structure based drug design (target-ligand docking)
Topics	– Introduction to drug designing – Data mining, literature study and acquisition of target structure Databases- NCBI, PDB, RCSB, UNIPROT, Modbase – Comparative modeling of protein (Homology modeling) target structure not available – Server based –PHYRE, RaptorX, SWISSMODEL, I-TASSER etc – Software based–Modeller(standalone) – Protein structure validation – Ramachandran plot assessment –RAMPAGE,Pdbsum , Procheck and Profiles3d – Molecular Docking (AutoDockTools)(file to file command explanation) – Active site Pocket identification -MetaPocket, CastP etc – Protein and ligand preparation – Setting grid parameters and Docking parameters -Setting up docking on command line -Docking analysis (based on binding energy, Hydrogen bonds, electrostatic interaction, hydrophobic interaction etc) -ADT (Auto Dock vina for multiple ligands) -BINANA (BINding ANAlyser) – Pdbsum Building protein-ligand complex and visualization

Who can apply for Training?

B.Tech. in (Biotechnology/ Industrial Biotechnology/ Bioinformatics/Material Sciences/Computer Sciences)

M.Sc. in (Biotechnology/Microbiology/Chemistry/Biochemistry/Bioinformatics/Life sciences/Material Sciences)

M.Tech. in (Biotechnology/Bioinformatics/ Industrial Biotechnology/Computer Sciences)

B. Pharmacy/M.Pharmacy

Protein Modeling and Molecular Dynamics Simulations

Dr. Suresh Gorle — Tue, 08 Feb 2022 11:31:12 +0000

The Protein Modeling and Simulations course offers hands-on training in a specific research area. Students will learn about the structural features and stability of protein structures, as well as model mutations using single and multiple amino acid substitutions. The effects of these mutations on protein structure will be studied using state-of-the-art Molecular Dynamics simulations. Additionally, the course covers the interaction of target proteins with specific ligand molecules, such as inhibitors or activators. Overall, this course provides a comprehensive understanding of protein structure and function through simulations and analysis.