Applied Metallomics:
A groundbreaking survey of a field that unites the sciences.
The metallome of a cellular compartment, such as an enzyme, is the variety and arrangement of its metal ions. Metallomics is the multidisciplinary study of the metallome and its many important interactions with biological molecules and systems. It exists at the intersection of biochemistry and materials science, offering crucial insights into biological processes in which iron, for instance, plays a pivotal role.
Applied Metallomics is an up-to-the-minute overview of research developments in metallomics, offering both analysis and applications in a vast array of scientific and industrial areas. Moving freely between material science, environmental science, health science, and more, it offers a comprehensive survey of this interdisciplinary research area. As the field of metallomics continues to develop and its applications expand, this book will only be a need of the hour.
Applied Metallomics readers will also find:
Detailed treatment of nanometallomics, environmetallomics, agrometallomics, and many more.
Coverage of machine learning and artificial intelligence techniques with applications in metallomics.
An author team with vast international research experiences.
Applied Metallomics is ideal for researchers in many areas touched by metallomics, that include chemistry, biochemistry, biotechnology, bioinorganic chemistry, and more.
Author(s): Li Y.-F., Sun H. (ed.)
Publisher: WILEY-VCH
Year: 2024
Language: English
Pages: 495
Cover
Half Title
Applied Metallomics: From Life Sciences to Environmental Sciences
Copyright
Contents
Foreword
Preface
1. Introduction
1.1 A Brief Introduction to Metallomics
1.2 Key Issues and Challenges in Metallomics
1.3 About the Structure of this Book
References
2. Nanometallomics
2.1 The Concept of Nanometallomics
2.2 The Analytical Techniques in Nanometallomics
2.2.1 The Analytical Techniques for Size Characterization of Nanomaterials in Biological System
2.2.1.1 Chromatography‐based Techniques for Size Characterization
2.2.1.2 Mass‐spectrometry‐based Techniques for Size Characterization
2.2.1.3 Laser, X‐rays, and Neutron‐beam‐based Techniques for Size Characterization
2.2.2 The Analytical Techniques for Quantification of Nanomaterials and Metallome in Biological System
2.2.3 The Analytical Techniques for Studying the Distribution of Nanomaterials in Biological System
2.2.4 The Analytical Techniques for Studying the Metabolism of Nanomaterials in Biological System
2.3 The Application of Nanometallomics in Nanotoxicology
2.3.1 Understanding the Size Changes, Uptake and Excretion, Distribution, and Metabolism of Nanomaterials in Biological Systems
2.3.2 Comparative Nanometallomics for Distinguishing Nanomaterials Exposure and Nanosafety Evaluation
2.4 Conclusions and Perspectives
Acknowledgments
References
3. Environmetallomics
3.1 The Concept of Environmetallomics
3.2 The Analytical Techniques in Environmetallomics
3.2.1 The Requirements for Environmetallome Analysis
3.2.2 Quantitative Analysis for Environmetallomics
3.2.3 Metal Distribution and Mapping for Environmetallomics
3.2.4 Metal Speciation for Environmetallomics
3.2.5 Metalloprotein Analysis
3.3 The Application of Environmetallomics in Environmental Science and Ecotoxicological Science and the Perspectives
Acknowledgments
References
4. Agrometallomics
4.1 The Concept of Agrometallomics
4.1.1 Introduction
4.1.2 Agrometallomics and its Concept
4.2 Analytical Techniques in Agrometallomics
4.2.1 Sensitivity and Multi‐elemental Analysis in Agrometallomics
4.2.1.1 Mass Spectrometry in Agrometallomics
4.2.1.2 Atomic Spectrometry for Agrometallomics
4.2.2 Elemental Speciation and State Analysis in Agrometallomics
4.2.2.1 Chromatographic Hyphenation for Atomic Spectrometry or Mass Spectrometry
4.2.2.2 Synchrotron Radiation Analysis
4.2.2.3 Energy Spectroscopy Based on X‐ray
4.2.3 Spatial Distribution and Micro‐analysis Techniques in Agrometallomics
4.2.3.1 Laser Ablation Inductively Coupled Plasma Mass Spectrometry
4.2.3.2 Electrothermal Vaporization Hyphenation Technique
4.2.3.3 Laser‐induced Breakdown Spectroscopy
4.2.3.4 Single‐Cell and Micro‐particle Analysis
4.3 Application and Perspectives of Agrometallomics in Agricultural Science and Food Science
4.3.1 Agricultural Plants and Fungi and Derived Food
4.3.2 Agricultural Animal and Derived Food
4.3.2.1 Application of Sensitivity and Multielemental Analysis in Agricultural Animals
4.3.2.2 Application of Elemental Speciation and State Analysis in Agricultural Animals
4.3.2.3 Application of Spatial Distribution and Micro‐analysis in Agricultural Animals
4.3.3 Soil, Water, and Fertilizer for Agriculture
References
5. Metrometallomics
5.1 The Concept of Metrometallomics
5.2 The Analytical Techniques in Metrometallomics
5.2.1 Analytical Techniques of Protein Quantification in Metrometallomics
5.2.2 Analytical Techniques of Quantitative In Situ Analysis in Metrometallomics
5.3 The Application of Metrometallomics in Life Science and the Perspectives
5.3.1 Absolute Quantification of Metalloproteins in Metrometallomics
5.3.1.1 Naturally Present Elements (P, S, Se, Metals)
5.3.1.2 Elemental Labeling
5.3.1.3 Directly Protein Tagging (I, Hg, Chelate Complexes)
5.3.1.4 Immunological Tagging
5.3.1.5 Direct Quantification of Proteins by LA‐ICP‐MS
5.3.1.6 Calibration for Metalloprotein Quantification by ICP‐MS
5.3.1.7 Perspectives of Absolute Quantification of Metalloproteins
5.3.2 Calibration Strategies of Quantitative In Situ Analysis in Metrometallomics
5.3.2.1 Internal Standardization
5.3.2.2 External Calibration
5.3.2.3 Calibration by Isotope Dilution
5.3.2.4 Perspectives of Quantitative In Situ Analysis in Metrometallomics
Acknowledgments
References
6. Medimetallomics and Clinimetallomics
6.1 The Concept of Medimetallomics and Clinimetallomics
6.1.1 Medimetallomics
6.1.2 Clinimetallomics
6.2 The Analytical Techniques in Medimetallomics and Clinimetallomics
6.2.1 Total Analysis of Clinical Elements
6.2.1.1 Atomic Spectroscopy Detection Technology
6.2.1.2 Mass Detection Technology
6.2.1.3 Electrochemical Analysis
6.2.1.4 Neutron Activation Analysis
6.2.2 Clinical Element Morphology and Valence Analysis Technology
6.2.2.1 Atomic Spectroscopy Detection Technology
6.2.2.2 Mass Spectrometry Detection Technology
6.2.3 Summary and Outlook
6.3 The Application of Medimetallomics and Clinimetallomics in Medical and Clinical Science and the Perspectives
6.3.1 Medimetallomics
6.3.1.1 Global or National Medimetallomics Research
6.3.1.2 Standardized Protocol for Medimetallomics Research
6.3.1.3 The Application of Medimetallomics Results
6.3.1.4 Next Steps and Opportunities for Medimetallomics
6.3.2 Clinimetallomics
6.3.2.1 Diseases Associated with Trace Elements
6.3.2.2 Toxic‐Element‐Related Diseases
6.3.2.3 Combined Toxicity of Multiple Heavy Metal Mixtures
6.3.2.4 Genetic Diseases Associated with Metallomics
6.3.2.5 Application of Metallomics in Disease Treatment
6.3.2.6 Perspectives
References
7. Matermetallomics
7.1 The Concept of Matermetallomics
7.1.1 Introduction
7.1.2 Metallic Elements as Dopant
7.1.3 Metallic Elements as Impurities
7.1.4 Metallic Elements as Crosslinkers
7.2 The Analytical Techniques in Matermetallomics
7.2.1 Element Imaging Analysis
7.2.1.1 Laser Ablation Inductively Coupled Plasma Mass Spectrometry (LA‐ICP‐MS)
7.2.1.2 Laser‐Induced Breakdown Spectroscopy (LIBS)
7.2.1.3 Secondary Ion Mass Spectrometry (SIMS)
7.2.1.4 TEM/X‐EDS
7.2.1.5 Synchrotron Radiation X‐Ray Fluorescence Spectrometry (SR‐XRF)
7.2.2 Quantitative and Qualitative Analysis
7.2.2.1 Inductively Coupled Plasma Atomic Emission Spectrometry (ICP‐AES)
7.2.2.2 Inductively Coupled Plasma Mass Spectrometry (ICP‐MS)
7.2.2.3 X‐Ray Fluorescence (XRF)
7.2.2.4 GD Optical Emission Spectroscopy (GD‐OES) and GD Mass Spectrometry (GD‐MS)
7.2.3 Metal Speciation Analysis
7.2.3.1 Raman Spectroscopy
7.2.3.2 X‐Ray Photo Electron Spectroscopy (XPS)
7.2.4 Techniques Providing Depth Information
7.3 The Application of Matermetallomics in Material Science and the Perspectives
7.3.1 Matermetallomics in Semiconductor Materials
7.3.2 Matermetallomics in Artificial Crystal Materials
Acknowledgments
References
8. Archaeometallomics
8.1 The Concept of Archaeometallomics
8.2 The Analytical Techniques in Archaeometallomics
8.2.1 Neutron Activation Analysis (NAA)
8.2.2 X‐Ray Fluorescence Analysis (XRF)
8.2.3 Laser Ablation Inductively Coupled Plasma Mass Spectrometry (LA‐ICP‐MS)
8.2.4 Laser‐induced Breakdown Spectroscopy (LIBS)
8.2.5 Atomic Absorption Spectroscopy (AAS)
8.2.6 X‐Ray Absorption Fine Structure Spectroscopy (XAFS)
8.2.7 X‐Ray Diffraction (XRD)
8.2.8 Neutron Diffraction
8.3 The Application of Archaeometallomics in Archaeological Science
8.3.1 The Application of Archaeometallomics in Ancient Ceramics
8.3.1.1 Archaeometallomics in Studying the Origin and Dating of Ancient Ceramics
8.3.1.2 Archaeometallomics in Studying the Color Mechanism and Firing Technology of Ancient Ceramics
8.3.2 The Application of Archaeometallomics in Metal Cultural Relics
8.3.2.1 Archaeometallomics in Studying the Origin of Metal Cultural Relics
8.3.2.2 Archaeometallomics in Studying the Manufacturing Technology of Metal Cultural Relics
8.3.2.3 Archaeometallomics in Studying the Corrosion of Metal Cultural Relics
8.3.3 The Application of Archaeometallomics in Ancient Painting
8.3.3.1 Archaeometallomics in Studying the Aging Mechanism of Painting Cultural Relics
8.3.3.2 Archaeometallomics in Studying the Authenticity Identification of Painting Cultural Relics
8.4 Summary and Perspectives
Acknowledgments
References
9. Metallomics in Toxicology
9.1 Metallomic Research on the Toxicology of Metals
9.2 Recent Progresses in Understanding the Health Effects of Heavy Metals
9.2.1 Mercury, Oxidative Stress, and Cell Death
9.2.2 Arsenic and Lung Cancer
9.2.3 Epigenetic Effects of Cadmium
9.2.4 Nephrotoxicity of Uranium in Drinking Water
9.3 Knowledge Gaps, Challenges, and Perspectives
Acknowledgments
List of Abbreviations
References
10. Pathometallomics: Taking Neurodegenerative Disease as an Example
10.1 Introduction to Pathometallomics
10.1.1 The Concept and Scope of Pathometallomics
10.1.2 Brief Introduction to Methodologies for Pathometallomics
10.2 Application of Pathometallomics in Neurodegenerative Diseases
10.2.1 Pathometallomics in Alzheimer's Disease
10.2.1.1 Dysregulation of Metal Homeostasis in AD
10.2.1.2 Metal‐Associated Dysfunction in AD
10.2.1.3 Application of Metallomics in the Prognosis of AD
10.2.1.4 Metal Chelators as AD Therapeutics
10.2.2 Pathometallomics in Parkinson's Disease
10.2.2.1 Dysregulation of Metal Homeostasis in PD
10.2.2.2 Application of Metallomics in the Prognosis of PD
10.2.2.3 Application of Metallodrugs and Metalloproteins in the Treatment of PD
10.2.3 Pathometallomics in Amyotrophic Lateral Sclerosis
10.2.3.1 Dysregulation of Metal Homeostasis in ALS
10.2.3.2 Metal‐Associated Dysfunction in ALS
10.2.4 Pathometallomics in Autism Spectrum Disorder
10.3 The Perspectives of Pathometallomics
Acknowledgments
References
11. Oncometallomics: Metallomics in Cancer Studies
11.1 Introduction to Oncometallomics
11.2 The Application of Oncometallomics in Cancer Studies
11.2.1 The Application of Oncometallomics in Cancer Diagnosis
11.2.1.1 Prostate Cancer
11.2.1.2 Breast Cancer
11.2.1.3 Lung Cancer
11.2.1.4 Gastric Cancer
11.2.1.5 Colorectal Cancer
11.2.1.6 Esophageal Cancer
11.2.1.7 Liver Cancer
11.2.1.8 Ovarian Cancer
11.2.1.9 Cervical Cancer
11.2.1.10 Thyroid Cancer
11.2.2 The Application of Oncometallomics in Cancer Treatment
11.3 The Metallome that Involved in the Occurrence and Development of Cancer
11.4 Conclusions and Perspectives
Acknowledgments
References
12. Bio-elementomics
12.1 Introduction
12.1.1 The Concept of Bio‐elementomics
12.1.2 The Development History of Bio‐elementomics
12.1.3 Research Scope
12.2 Basic Laws of Bio‐elementomics
12.2.1 Review of Bio‐elementomics
12.2.2 Organizational Selectivity of Bio‐elements
12.2.3 Specific Correlation of Bio‐elements
12.2.4 Orderliness of Bio‐elements
12.2.5 Diversity of Bio‐elements
12.2.6 Biological Fractionation
12.2.7 The Correlation Between the Bio‐elementomes and Other “Omes”
12.3 Rare‐Earth Elementome
12.3.1 Association of Rare‐Earth Elements and Related Diseases
12.3.2 The Mechanism Studies of the Hormesis Effect of REEs Based on the Bio‐elementomics
12.3.3 Beneficial Rebalancing Hypothesis for Hormesis Effect
12.4 Limitations of Bio‐elementomics
12.4.1 Statistically Higher Level of Some Elements in the Patient's Body
12.4.2 Environment‐independent Biomarkers
12.4.3 Trace Elements in Immortalized Lymphocytes
12.5 Perspectives
12.5.1 Speciation Analysis of Elements
12.5.2 Bio‐elements and Their Interactions with Proteins, Genes, and Small Molecules
12.5.3 Research Based on the Hormesis “Beneficial Rebalancing” Hypothesis
12.5.4 Multi‐element Analysis of Immortalized Lymphocytes
12.5.5 Analysis of Bio‐elements in Single Cell
References
13. Methodology and Tools for Metallomics
13.1 Brief Description of Metallomics
13.1.1 Why Do Research on Biometals?
13.1.2 What's the Goal of Metallomics?
13.1.3 How to Perform a Metallomic Study?
13.2 Methodologic Strategy for Metallomic Research
13.2.1 In Vivo
13.2.2 Ex Vivo
13.2.3 In Vitro
13.2.4 In Silico
13.3 Tools for Metallomics
13.3.1 Tools for Quantitative Metallomics
13.3.2 Tools for Qualitative Metallomics
13.3.3 Imaging Tools for Metallomics
13.4 Concluding Remarks
References
14. ICP-MS for Single-Cell Analysis in Metallomics
14.1 Introduction
14.2 ICP‐MS Instrumental Optimization for Single‐Cell Analysis
14.2.1 Sample Introduction System
14.2.1.1 Pneumatic Nebulization
14.2.1.2 Laser Ablation
14.2.2 Mass Analyzer and Detector
14.3 Microfluidic Platform for Single‐Cells Analysis
14.3.1 Droplet‐Encapsulation‐Based Single‐Cell Separation
14.3.2 Hydrodynamic‐Capture‐Based Single‐Cell Separation
14.3.3 Magnetic‐Separation‐Based Single‐Cell Capture
14.4 ICP‐MS‐Based Single‐Cells Analysis in Metallomics
14.4.1 Endogenous Elements in Single Cells
14.4.2 Exogenous Metal Exposure to Single Cells
14.4.3 Nanoparticles Uptake by Single Cells
14.4.4 Metal‐containing Drugs Uptake by Single Cells
14.4.5 Biomolecular Quantification at Single‐Cell Level
14.4.6 Other Applications
14.5 Summary and Perspectives
References
15. Novel ICP-MS-based Techniques for Metallomics
15.1 Introduction
15.2 ICP‐MS: A Powerful Method in Metallomics
15.2.1 Solution Introduction System and Plasma Source
15.2.2 Time‐of‐flight Mass Analyzer
15.2.3 Laser Ablation Systems
15.3 Recent Advances in ICP‐MS‐based Metallomics
15.3.1 Single‐particle Analysis
15.3.2 Single‐cell Analysis
15.3.3 Spatial Metallomics
15.4 Conclusions
Acknowledgment
References
16. Machine Learning for Data Mining in Metallomics
16.1 Data Mining Methods in Metallomics
16.1.1 Data Preprocessing
16.1.1.1 Smoothing Process
16.1.1.2 Normalization
16.1.1.3 Fourier Transform
16.1.1.4 Wavelet Transform
16.1.1.5 Convolution Operation
16.1.2 Data Dimensionality Reduction
16.1.2.1 Principal Component Analysis
16.1.2.2 Independent Component Analysis
16.1.2.3 Multidimensional Scaling
16.1.2.4 Local Preserving Projection
16.1.2.5 T‐Stochastic Neighbor Embedding
16.1.3 Sample Set Division
16.1.3.1 Random Sampling
16.1.3.2 Kennard–Stone Sampling
16.1.3.3 Sample Set Partitioning Based on Joint x−y Distances
16.1.3.4 Cross‐Validation
16.1.3.5 Leave‐One‐Out Cross Validation
16.1.4 Predictive Model Building Method
16.1.4.1 Partial Least Squares Regression
16.1.4.2 Support Vector Machine
16.1.4.3 Decision Tree
16.1.4.4 K‐means Clustering
16.1.4.5 Deep Learning
16.1.5 Model Evaluation
16.1.5.1 Evaluation Index of the Quantitative Model
16.1.5.2 Evaluation Indicators of the Qualitative Model
16.2 Application of Machine Learning for Data Mining in Metallomics
16.2.1 Applications in Medical Science
16.2.2 Applications in Agricultural Science
16.2.3 Applications in the Environmental Science
References
Index
