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  • Biomedical Signal Analysis
    Biomedical Signal Analysis

    Biomedical Signal Analysis Comprehensive resource covering recent developments, applications of current interest, and advanced techniques for biomedical signal analysis Biomedical Signal Analysis provides extensive insight into digital signal processing techniques for filtering, identification, characterization, classification, and analysis of biomedical signals with the aim of computer-aided diagnosis, taking a unique approach by presenting case studies encountered in the authors’ research work. Each chapter begins with the statement of a biomedical signal problem, followed by a selection of real-life case studies and illustrations with the associated signals.Signal processing, modeling, or analysis techniques are then presented, starting with relatively simple “textbook” methods, followed by more sophisticated research-informed approaches.Each chapter concludes with solutions to practical applications.Illustrations of real-life biomedical signals and their derivatives are included throughout.The third edition expands on essential background material and advanced topics without altering the underlying pedagogical approach and philosophy of the successful first and second editions.The book is enhanced by a large number of study questions and laboratory exercises as well as an online repository with solutions to problems and data files for laboratory work and projects.Biomedical Signal Analysis provides theoretical and practical information on: The origin and characteristics of several biomedical signalsAnalysis of concurrent, coupled, and correlated processes, with applications in monitoring of sleep apneaFiltering for removal of artifacts, random noise, structured noise, and physiological interference in signals generated by stationary, nonstationary, and cyclostationary processesDetection and characterization of events, covering methods for QRS detection, identification of heart sounds, and detection of the dicrotic notchAnalysis of waveshape and waveform complexityInterpretation and analysis of biomedical signals in the frequency domainMathematical, electrical, mechanical, and physiological modeling of biomedical signals and systemsSophisticated analysis of nonstationary, multicomponent, and multisource signals using wavelets, time-frequency representations, signal decomposition, and dictionary-learning methods Pattern classification and computer-aided diagnosis Biomedical Signal Analysis is an ideal learning resource for senior undergraduate and graduate engineering students.Introductory sections on signals, systems, and transforms make this book accessible to students in disciplines other than electrical engineering.

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  • Biomedical Science Practice
    Biomedical Science Practice

    The Fundamentals of Biomedical Science series has been written to reflect the challenges of practicing biomedical scientists today.It draws together essential basic science, with insights into laboratory practice, to show how an understanding of the biology of disease is linked to analytical approaches that lead to diagnosis.The series reviews the full range of disciplines to which a biomedical scientist may be exposed - from microbiology, to cytopathology, to transfusion science. The third edition of Biomedical Science Practice gives a comprehensive overview of key laboratory techniques and professional practial skills, with which students will need to be familiar to be successful in a professional biomedical enviroment.The text discusses a broad range of professional skills and concepts, such as health and safety considerations, personal development, and communication and confidentiality.The text also explores key experimental and analytical approaches which form the basis of the investigation and diagnosis of clinical conditions. Each chapter is supported with engaging clinical case studies, written to emphasize the link between theory and practice, and a set of end-of-chapter questions, which encourages students to test their knowledge and stretch their understanding. The third edition is available for students and institutions to purchase in a variety of formats and is supported by online resources. The e-book offers a mobile experience and convenient access along with functionality tools, navigation features and links that offer extra learning support: www.oxfordtextbooks.co.uk/ebooksOnline student resources supporting the book include:- Video podcasts including interviews with practicing biomedical scientists- 'In the lab' footage of key practical techniques, showing biomedical science in practice Online lecturer resources supporting the book include:Figures from the book, available to download

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  • Biomedical Photonic Technologies
    Biomedical Photonic Technologies

    Biomedical Photonic Technologies A state-of-the-art examination of biomedical photonic research, technologies, and applications In Biomedical Photonic Technologies, a team of distinguished researchers delivers a methodical inquiry and evaluation of the latest developments in the field of biomedical photonics, with a focus on novel technologies, including optical microscopy, optical coherence tomography, fluorescence imaging-guided surgery, photodynamic therapy dosimetry, and optical theranostic technologies.Each discussion of individual technologies includes examples of their contemporary application in areas like cancer therapy and drug delivery.Readers will discover the major research advancements in biomedical photonics from the last 20 years, ascertaining the basic principles of formation, development, and derivation of biomedical photonics phenomena at a variety of scales.Readers will also find: A thorough introduction to advanced wide-field fluorescent microscopy for biomedicine Comprehensive explorations of fluorescence resonance energy transfer and optical coherence tomography for structural and functional imaging Practical exploration of coherent Raman scattering microscopy and biomedical applications, as well as fluorescence image-guided surgery Complete analyses of enhanced photodynamic therapy, optogenetics, and optical theranostics employing gold nanoparticles Perfect for biophysicists and applied physicists, Biomedical Photonic Technologies will also benefit bioengineers and biotechnologists in academia and in industry.

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  • ENGLISH FOR BIOMEDICAL SCIENCES
    ENGLISH FOR BIOMEDICAL SCIENCES


    Price: 24.00 £ | Shipping*: 3.99 £
  • What are biomedical disease models?

    Biomedical disease models are tools used in research to study and understand human diseases. These models can be in the form of cell cultures, animal models, or computer simulations that mimic the characteristics and progression of a specific disease. By using these models, researchers can investigate the underlying mechanisms of diseases, test potential treatments, and develop new therapies to improve human health. Overall, biomedical disease models play a crucial role in advancing our knowledge of diseases and finding ways to prevent, diagnose, and treat them effectively.

  • What does a biomedical engineer do?

    A biomedical engineer applies engineering principles and design concepts to medicine and biology for healthcare purposes. They work on developing medical devices, equipment, and software to improve patient care and treatment outcomes. Biomedical engineers also conduct research to solve clinical problems and improve healthcare technologies. Their work involves collaborating with healthcare professionals, scientists, and other engineers to create innovative solutions for the medical field.

  • What is a biomedical specialist analyst?

    A biomedical specialist analyst is a professional who specializes in analyzing and interpreting data related to biomedical research and healthcare. They use their expertise to evaluate the effectiveness of medical treatments, identify trends in disease prevalence, and assess the impact of new technologies on patient outcomes. These analysts play a crucial role in helping healthcare organizations make informed decisions and improve patient care. They may work in a variety of settings, including hospitals, research institutions, pharmaceutical companies, and government agencies.

  • Where can one study Biomedical Analytics?

    One can study Biomedical Analytics at various universities and colleges that offer programs in health informatics, bioinformatics, or biomedical data science. Some well-known institutions that offer programs in Biomedical Analytics include Stanford University, Harvard University, Johns Hopkins University, and the University of California, Los Angeles. Additionally, there are online programs and professional certifications available for those looking to specialize in Biomedical Analytics.

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  • Introduction to Biomedical Engineering
    Introduction to Biomedical Engineering

    Introduction to Biomedical Engineering, Fourth Edition is a comprehensive survey text for biomedical engineering courses.It is the most widely adopted text across the BME course spectrum, valued by instructors and students alike for its authority, clarity and encyclopedic coverage in a single volume.Biomedical engineers need to understand the wide range of topics that are covered in this text, including basic mathematical modeling, anatomy and physiology, electrical engineering, signal processing and instrumentation, biomechanics, biomaterials science, tissue engineering and medical and engineering ethics.The authors tackle these core topics at a level appropriate for senior undergraduate students and graduate students who are either majoring in BME or studying it as a combined course with a related engineering, biology or life science, or medical/pre-medical course.

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  • Writing for Biomedical Sciences Students
    Writing for Biomedical Sciences Students

    This book will equip readers with all the skills needed to write convincing and polished assignments in biomedical sciences.The first part introduces the idea of writing for one’s audience and enables readers to understand what’s expected of them from different types of assignment.Part two provides detailed guidance on specific writing and presentation tasks, with individual chapters on essays, lab reports, reflective writing, posters and presentations.Parts three and four cover all of the key skills needed for successful writing in the biomedical sciences and help students develop a critical eye when selecting and researching information and create clear, well-structured assignments.Chapters contain top tips, examples and helpful summaries of key points, and three annotated sample assignments are provided in an appendix. This is an essential companion to any student studying biomedical science or related disciplines such as physiology, biomedical engineering, pharmacy, medicine and dentistry.

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  • Swarm Optimization for Biomedical Applications
    Swarm Optimization for Biomedical Applications

    Biomedical engineering is a rapidly growing interdisciplinary area that is providing solutions to biological and medical problems and improving the healthcare system.It is connected to various applications like protein structure prediction, computer-aided drug design, and computerized medical diagnosis based on image and signal data, which accomplish low-cost, accurate, and reliable solutions for improving healthcare services.With the recent advancements, machine learning (ML) and deep learning (DL) techniques are widely used in biomedical engineering to develop intelligent decision-making healthcare systems in real-time.However, accuracy and reliability in model performance can be a concern in tackling data generated from medical images and signals, making it challenging for researchers and practitioners.Therefore, optimized models can produce quality healthcare services to handle the complexities involved in biomedical research. Various optimization techniques have been employed to optimize parameters, hyper-parameters, and architectural information of ML/DL models explicitly applied to biological, medical, and signal data.The swarm intelligence approach has the potential to solve complex non-linear optimization problems.It mimics the collective behavior of social swarms such as ant colonies, honey bees, and bird flocks.The cooperative nature of swarms can search global settings of ML/DL models, which efficiently provide the solution to biomedical engineering applications.Finally, the book aims to provide the utility of swarm optimization and similar optimization techniques to design ML/DL models to improve the solutions related to biomedical engineering.

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  • Biomedical Research, Medicine, and Disease
    Biomedical Research, Medicine, and Disease

    Biomedical research is the first step towards the creation of new medications and treatments that help to manage different types of health conditions and diseases.The prevention and cure of diseases would be practically impossible without such type of research.Although the drug discovery and development processes are far too costly, time-consuming, prone to failure, and have low success rate, today the term "translational research or medicine" seems to have become trendy, yet it is insufficient.The present book is a sincere attempt by dedicated researchers to convey the importance of translational biomedical research, medicine, and disease, primarily, basic and clinical difficulties in the translation of diagnostic measures, pharmaceutical advances, biomarkers, diagnostics, and therapeutics. This book is meant for researchers, scientists, healthcare professionals, industry, innovators, and students of biomedical sciences, as well as for those involved in the basic sciences, biochemistry, biotechnology, biophysics, and life sciences in general. The volume comprehensively covers:Emerging technologies for health careVarious aspects of biomedical research toward understanding of pathophysiology of the diseasesAdvances in improvement in diagnostic procedures and therapeutic toolsThe fundamental role of biomedical research in the development of new medicinal products

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  • Is there a difference between medical technology and biomedical engineering?

    Yes, there is a difference between medical technology and biomedical engineering. Medical technology refers to the tools, equipment, and procedures used in healthcare to diagnose, monitor, and treat patients. Biomedical engineering, on the other hand, is a field that combines principles of engineering and biology to develop innovative solutions for healthcare challenges. Biomedical engineers design and create medical devices, equipment, and systems to improve patient care and advance medical research. In summary, medical technology is a component of healthcare that includes products and procedures, while biomedical engineering is a specialized field that focuses on applying engineering principles to healthcare.

  • How can one become self-employed as a biomedical engineer?

    To become self-employed as a biomedical engineer, one can start by gaining experience and expertise in the field through education and work experience. It is important to build a strong network of contacts within the industry to potentially secure clients or projects. Developing a business plan and identifying a niche market within biomedical engineering can help set one apart from competitors. Additionally, obtaining any necessary certifications or licenses and staying current with advancements in the field can help ensure success as a self-employed biomedical engineer.

  • How can one transition from a biomedical analyst to forensics?

    To transition from a biomedical analyst to forensics, one could consider pursuing additional education or training in forensic science or a related field. This could involve obtaining a certification or a master's degree in forensic science. It may also be beneficial to gain experience through internships or volunteer opportunities in forensic labs or with law enforcement agencies. Networking with professionals in the field of forensics and attending relevant conferences or workshops can also help in making the transition.

  • What are the differences between medical technology and biomedical engineering?

    Medical technology refers to the tools, equipment, and techniques used in healthcare to diagnose, monitor, and treat patients. This can include devices like MRI machines, surgical instruments, and diagnostic tests. Biomedical engineering, on the other hand, is a field of engineering that focuses on applying engineering principles and design concepts to medicine and biology. Biomedical engineers work to develop new medical devices, improve existing technologies, and create innovative solutions to healthcare challenges. While medical technology is the practical application of healthcare tools, biomedical engineering involves the research, development, and design of these tools.

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