Computational Chemistry Applied in the Analyses of Chitosan/Polyvinylpyrrolidone/Mimosa Tenuiflora

NORMA AUREA RANGEL-VÁZQUEZ, FRANCISCO RODRÍGUEZ FÉLIX  © by the authors

ISBN: 978-1-940366-00-5
Published Date: April, 2014
Pages: 91
Paperback: $80
Publisher: Science Publishing Group
To purchase hard copies of this book, please email: book@sciencepublishinggroup.com
Book Description

Computational chemistry allows using various models analyze and predict the behavior of single and composite materials to determine the composition of new materials.

It should be noted that a model is a representation of the construction and working of some system of interest. A model is similar to but simpler than the system it represents. One purpose of a model is to enable the analyst to predict the effect of changes to the system. On the one hand, a model should be a close approximation to the real system and incorporate most of its salient features. On the other hand, it should not be so complex that it is impossible to understand and experiment with it. A good model is a judicious tradeoff between realism and simplicity.

This book is aimed at researchers and students with basic knowledge of computational chemistry, interested in analyzing and discussing the structural properties of different polymers. It should be noted that this book is carried out an analysis of polymers such as Chitosan, PVP and MT as well as the structure of the model from the mixture of these polymers using a computational analysis using a comparison between PM3 and AM1 semi-empirical methods, respectively.

In this case, Chitosan is a linear polysaccharide composed of randomly distributed β-(1-4)-linked D-glucosamine (deacetylated unit) and N-acetyl-D-glucosamine (acetylated unit). It is made by treating shrimp and other crustacean shells with the alkali sodium hydroxide. Chitosan has a number of commercial and possible biomedical uses. It can be used in agriculture as a seed treatment and biopesticide, helping plants to fight off fungal infections. In winemaking it can be used as a fining agent, also helping to prevent spoilage. In industry, it can be used in a self-healing polyurethane paint coating. In medicine, it may be useful in bandages to reduce bleeding and as an antibacterial agent; it can also be used to help deliver drugs through the skin.

PVP was first synthesized by Walter Reppe and a patent was filed in 1939 for one of the most interesting derivatives of acetylene chemistry. PVP was initially used as a blood plasma substitute and later in a wide variety of applications in medicine, pharmacy, cosmetics and industrial production. It is used as a binder in many pharmaceutical tablets; it simply passes through the body when taken orally. However, autopsies have found that crospovidone does contribute to pulmonary vascular injury in substance abusers who have injected pharmaceutical tablets intended for oral consumption. The long-term effects of crospovidone within the lung are unknown. PVP added to iodine forms a complex called povidone-iodine that possesses disinfectant properties. This complex is used in various products like solutions, ointment, pessaries, liquid soaps and surgical scrubs. It is known under the trade name Betadine and Pyodine. It is used in pleurodesis (fusion of the pleura because of incessant pleural effusions). For this purpose, povidone iodine is equally effective and safe as talc, and may be preferred because of easy availability and low cost

Finally, Mimosa tenuiflora, syn. Mimosa hostilis (Jurema, Tepezcohuite) is a perennial tree or shrub native to the northeastern region of Brazil (Paraíba, Rio Grande do Norte, Ceará, Pernambuco, Bahia) and found as far north as southern Mexico (Oaxaca and coast of Chiapas). It is most often found in lower altitudes, but it can be found as high as 1000 m. Mimosa tenuiflora is a very good source of fuel wood and works very well for making posts, most likely because of its high tannin content (16%), which protects it from rot.

Due to its high tannin content, the bark of the tree is widely used as a natural dye and in leather production. It is used to make bridges, buildings, fences, furniture and wheels. It is an excellent source of charcoal and at least one study has been done to see why this is the case.

Finally, an important difference that has this book is, the analysis and determination of properties such as FTIR, electrostatic potentials and structural parameters of polymers in an individual way and in union, to propose a structure for a new material that has great features to be applied in the medical field and thus contribute to a need in society in general.

Author Introduction

NORMA AUREA RANGEL-VáZQUEZ, División de Estudios de Posgrado e Investigación del Instituto Tecnológico de Aguascalientes, Ave. López Mateos # 1801 Ote. Fracc. Bona Gens CP. 20256 Aguascalientes, Aguascalientes, México.
FRANCISCO RODRíGUEZ FéLIX, Departamento de Investigación y Posgrado en Alimentos. Universidad de Sonora, Blvd. Luis Encinas y Rosales S/N Col. Centro, Hermosillo, Sonora, México.
BáRBARA-SUSANA GREGORí-VALDéS, Institute for Biotechnology and Bioengineering, Centre for Biological and Chemical Engineering, Instituto Superior Técnico, Av. Rovisco Pais 1, 1049-001 Lisboa, Portugal.

Table of Contents
  • The Whole Book

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  • Front Matter

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  • Chapter 1 Molecular Modelation

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    1. 1.1 Introduction
    2. 1.2 Molecular Mechanics
    3. 1.3 Semi-Empirical Methods
    4. 1.3.1 AM1 Method
    5. 1.3.2 PM3 Method
    6. 1.4 Gibbs Energy Free
    7. 1.5 Electrostatic Potential
    8. 1.6 Molecular Orbitals
  • Chapter 2 Methodology

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    1. 2.1 Geometry Optimization
    2. 2.2 Structural Parameters
    3. 2.3 FTIR
    4. 2.4 Electrostatic Potential
    5. 2.5 Orbitals Molecular
    6. 2.6 Conclusions
  • Chapter 3 Chitosan

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    1. 3.1 Introduction
    2. 3.2 Synthesis
    3. 3.3 Applications
    4. 3.3.1 Drug Delivery
    5. 3.3.2 Tissue Engineering
    6. 3.4 Results and Discussion of Simulations Analyses
    7. 3.4.1 Optimization Energy
    8. 3.4.2 Structural Parameters
    9. 3.4.3 FTIR Analyses
    10. 3.4.4 Electrostatic Potential
    11. 3.4.5 Molecular Orbitals
    12. 3.4.6 Conclusions
  • Chapter 4 Polyvinylpyrrolidone (PVP)

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    1. 4.1 Introduction
    2. 4.2 Synthesis and Structure
    3. 4.3 Applications
    4. 4.4 Results and Discussion of Simulations Analyses
    5. 4.4.1 Optimization Energy
    6. 4.4.2 Structural Parameters
    7. 4.4.3 FTIR Analyses
    8. 4.4.4 Electrostatic Potential
    9. 4.4.5 Molecular Orbitals
    10. 4.4.6 Conclusions
  • Chapter 5 Mimosa Tenuiflora

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    1. 5.1 Introduction
    2. 5.2 Secondary Metabolites of Mimosa Tenuiflora
    3. 5.3 Results and Discussions of Simulations Analyses
    4. 5.3.1 Optimization Energy
    5. 5.3.2 Structural Parameters
    6. 5.3.3 FTIR Analyses
    7. 5.3.4 Electrostatic Potential
    8. 5.3.5 Molecular Orbitals
    9. 5.3.6 Conclusions
  • Chapter 6 Chitosan/PVP/Mimosa Tenuiflora

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    1. 6.1 Simulation Results
    2. 6.1.1 Optimization Geometry
    3. 6.1.2 FTIR Analyses
    4. 6.1.3 Electrostatic Potential
    5. 6.1.4 Molecular Orbitals
    6. 6.1.5 Conclusions
  • Back Matter

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