New York City has the largest medical examiner's office in the United States, and the Brooklyn division is the busiest of the five boroughs. Charles A. Catanese received his Forensic Pathology fellowship training in New York, and then worked full time as a Medical Examiner in the Brooklyn office for more than 10 years. He has personally performed more than 4000 autopsies, including over 400 homicides. Dr. Catanese has worked through several disasters, including TWA Flight 800, AA Flight 587, and more than nine months on the World Trade Center fatalities. He is currently the Chief Medical Examiner of Orange County, New York. Drawing on his wealth of knowledge and experience in solving some of the most difficult cases a forensic examiner could encounter, he assembles hundreds of images from his own work experience to present the Color Atlas of Forensic Medicine and Pathology. Featuring twice the number of images as any other forensic pathology atlas, the book is filled with high-resolution photos that demonstrate postmortem changes of the human body and the different types of patterns produced in deaths caused by: Natural causes Diagnostic or therapeutic procedures Substance abuse Poisoning Child abuse Firearms Blunt instruments Sharp instruments Burns Asphyxia This easy-to-read atlas, created for medical and non-medical personnel, covers basic and advanced forensic concepts that relate to all manners of deaths. The carefully worded, unambiguous text describing each photo and the side-by-side comparisons of similar, yet different, pathologies make this remarkable atlas a powerful teaching tool for all those who must confront and solve the mystery of human demise. A fully searchable DVD version is also available.

With every chapter revised and updated, Physics for Diagnostic Radiology, Third Edition continues to emphasise the importance of physics education as a critical component of radiology training. This bestselling text helps readers understand how various imaging techniques work, from planar analogue and digital radiology to computed tomography (CT), nuclear medicine, and positron emission tomography (PET) to ultrasound imaging and magnetic resonance imaging (MRI).

New to the Third Edition

• Material on digital receptors
• Emphasis on the differences between analogue and digital images
• Coverage of multi-slice CT and three-dimensional resolution, dual energy applications, and cone beam CT
• Special radiographic techniques, including subtraction techniques and interventional radiology
• New chapter on PET, with discussion of multi-modality imaging (PET/CT)
• Additional material on radiation doses and risks to patients
• New chapter covering picture archiving and communication system (PACS), teleradiology, networks, archiving, and related factors
• A summary of the main teaching points at the beginning of each chapter

After an introductory chapter on basic physics, the book follows the x-ray imaging process: production of x-rays, interaction with the patient, radiation measurement, the image receptor, the radiological image, and image quality assessment. It then covers more advanced x-ray techniques as well as imaging with radioactive materials. The text also focuses on radiobiology, risk and radiation protection, and imaging with non-ionising radiation. The final chapter discusses data handling in a modern, electronic radiology department.

While chemists using spectroscopic methods need to learn from the specialists, they do not normally read the spectroscopists' original papers. This book provides this very information -- summarizing some recent advances in the mechanistic understanding of metallocene polymerization catalysts and the role of NMR spectroscopy in these endeavors.
Adopting a real practice-oriented approach, the authors focus on two of the most important spectroscopic techniques with two parts devoted to each of NMR and IR spectroscopy - as well as on important industrial applications with regard to the reaction discussed. Rather than providing a complete and exhaustive review of homogeneous hydrogenation and its detailed mechanisms, the book focuses on the specific spectroscopic techniques and the mechanistic information that has been obtained from their application. The result is unique in its scope, allowing chemists from different fields to learn which techniques can be applied for their specific synthetic problems.
The prizewinning editor, Professor Brian Heaton, is the key player in the field, and has brought together here a team of authors to cater for specialists, and researchers in industry and academia.