- Shopping Bag ( 0 items )
Ships from: Naperville, IL
Usually ships in 1-2 business days
|Ch. 1||Legal Standards for the Admissibility of Novel Scientific Evidence||1|
|Factors Affecting Reliance by the Courts on Scientific Evidence||2|
|The Motion in Limine||3|
|Standards for Admissibility||5|
|Ch. 2||A Guide to the Analysis of Forensic Dust Specimens||24|
|Occurrence, Collection, and Preservation of Dust Specimens||26|
|Characterization and Identification Procedures||32|
|Ch. 3||Forensic Applications of Infrared Spectroscopy||71|
|Specificity and Limitations of Infrared Spectroscopy||95|
|Sampling Techniques and Accessories||116|
|Ch. 4||Infrared Microscopy and its Forensic Applications||196|
|Spectral Measurement Methods and Sample Preparation||214|
|Ch. 5||Forensic Pharmacology||253|
|Basic Principles of Pharmacology||254|
|Other Drugs of Interest to the Forensic Scientist||280|
|Ch. 6||Deoxyribonucleic Acid Structure and Function - A Review||287|
|The Watson-Crick Model of DNA||295|
|The Genetic Code||302|
|Methylation of Bases in DNA||306|
|Transaction and Translation||307|
|DNA Synthesis in the Cell Cycle||314|
|Plasmids as Gene-Cloning Vectors||332|
|DNA Profiling (RFLP Analysis)||333|
|Production of Transgenic Animals||344|
|Medical Benefits, Legal and Ethical Considerations||346|
|Ch. 7||Forensic DNA Typing of Highly Polymorphic VNTR LOCI||358|
|Fundamentals of DNA Structure||359|
|Genetic Markers Used for Forensic RFLP Typing||361|
|The RFLP Typing Procedure||363|
|Interpretation of RFLP Typing Results||381|
|Validity and Reliability of RFLP Typing and Data Interpretation||389|
|Appendix 7.1 Guidelines for a Quality Assurance Program for DNA Analysis||398|
|Ch. 8||DNA Analysis in Biological Evidence: Applications of the Polymerase Chain Reaction||416|
|The Polymerase Chain Reaction||417|
|Detection of Genetic Variation||424|
|Determination of Sex and Species Origin||433|
|Biological Evidence Analysis Using PCR||435|
|Interpretation of Results: Statistical Considerations||442|
Forensic science is no different from any other scientific discipline; its growth and vitality are inextricably linked to the continuous accumulation of knowledge through discovery and experience. Science builds on past accomplishments; its rate of progress is measured by the caliber of published data and results. The first edition of Forensic Science Handbook was published in 1982. This book eventually grew into the current three-volume series. The three Handbooks have proven to be widely circulated professional reference books, as well as standard textbooks for graduate courses in forensic science. For the foreseeable future, the Handbooks will remain a three-volume collection. For the most part, the subjects to be found in this second edition of Volume I remain the same as in the first edition, but with an updated content. However, there are some notable additions to this revision. The impact of DNA technology has fundamentally changed the way forensic analysts characterize biological stains. The chapter "Modern Forensic Biology" details the field collection of DNA evidence and proceeds with a methodical updated treatment of the forensic laboratory's strategy for analyzing biological stains. Also, entirely new chapters have been added to the Handbook on the subjects of capillary electrophoresis and visible spectrophotometry.
Forensic Science Handbook—Volume I places in one reference source authoritative, updated reviews embracing important areas of the criminalistic enterprise. The topics selected for inclusion in the Handbook are designed to provide the reader with material necessary to comprehend, evaluate, and appreciate the application andinterpretation of scientific tests to an array of physical evidence. Chapters are devoted to discussions of examination techniques for a wide range of evidence found in the modern crime laboratory—DNA, hair, paint, soil, glass, petroleum products, explosives, alcohol in blood and breath, and questioned documents. The expanding applications of mass spectrometry, capillary electrophoresis, high-performance liquid chromatography, and the visible microspectrophotometer warrant the inclusion of chapters describing their theory, operation, and forensic use. However, the emergence of modern analytical instruments has not diminished the importance of the light microscope in criminalistics. The microscope's unique role in the crime laboratory has prompted coverage of its operational theory and applications to forensic science problems.
A chapter describing the role and conduct of the expert witness and rules of evidence, as well as the legal requirements governing the admissibility of scientifically evaluated evidence, serves to emphasize the ties that bind forensic science to criminal law.
The contributors to this volume of the Handbook are all recognized forensic experts well versed in the practices of their chosen areas of expertise. The expectation is that these authors will be successful in communicating to the reader knowledge and lessons derived from their many years of practical experience in laboratories and courtrooms. The editor deeply appreciates the enthusiasm and skills each contributor brought to this project. Their efforts are a mark of their professionalism and dedication to continued achievement and excellence in forensic science.
I want to credit the efforts of Gonul Turhan, who aided me in reviewing the manuscript and tying up lots of loose ends while preparing the manuscript for production. I wish to express my appreciation to my production editor, Linda Pawelchak, for transforming the manuscript into a finished book. I also want to acknowledge my acquisition editor, Kim Davies, for supporting the Handbook volumes.
The views and opinions expressed in the book are those of the contributors and do not necessarily represent those of any governmental agency.
Richard Saferstein, Ph.D.
Mt. Laurel, New Jersey