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2019 | Book

Synthesis of Metallic and Metal Oxide Particles Read chapter Read first chapter

Biological Responses to Nanoscale Particles

Molecular and Cellular Aspects and Methodological Approaches

Editors: Prof. Dr. Peter Gehr, Prof. Dr. Reinhard Zellner

Publisher: Springer International Publishing

Book Series : NanoScience and Technology

Part of: Springer Professional "Wirtschaft+Technik" , Springer Professional "Technik"

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About this book

In this book the recent progress accumulated in studies of the interaction of engineered nanoparticles with cells and cellular constituents is presented. The focus is on manufacturing and characterization of nanosized materials, their interactions with biological molecules such as proteins, the mechanisms of transport across biological membranes as well as their effects on biological functions. Fundamental molecular and cellular aspects are in the foreground of the book. A further particularity is the interdisciplinary approach, including fields such as preparatory and analytical chemistry, biophysics and the physics of colloids, advanced microscopy and spectroscopy for in-situ detection of nanoparticles, cellular toxicology and nanomedicine.

Nanoscale particles are known to exhibit novel and unprecedented properties that make them different from their corresponding bulk materials. As our ability to control these properties is further advanced, a huge potential to create materials with novel properties and applications emerges. Although the technological and economic benefits of nanomaterials are indisputable, concerns have also been raised that nanoscale structuring of materials might also induce negative health effects. Unfortunately, such negative health effects cannot be deduced from the known toxicity of the corresponding macroscopic material. As a result, there is a major gap in the knowledge necessary for assessing their risk to human health.

Table of Contents

Frontmatter

Manufacturing and Characterization of Materials

Frontmatter
Chapter 1. Synthesis of Metallic and Metal Oxide Particles
Abstract
The diversity of applications in catalysis, energy storage and medical diagnostics utilizes unique and fascinating properties of metal and metal oxide nanostructures. Confined to the nanometer scale, materials may display properties that are different from the equivalent bulk compounds. To meet the requirements for various applications, numerous production techniques were developed to control particle size, morphology, aggregation state, crystal structure, surface charge and composition. This chapter presents an overview of the preparation of metallic and metal oxide nanoparticles by bottom-up and top-down approaches. We describe basic synthetic routes for prominent cases of metals (gold, silver, platinum and copper) and metal oxides (zinc oxide, titania, and silica).
Kateryna Loza, Matthias Epple
Chapter 2. Quantum Dots and Quantum Rods
Abstract
Quantum Dots are tiny nanocrystals of a few nanometers in size. Due to their unique optical and electronic properties they are one of the core issues in the field of nanotechnology. This chapter will cover fundamental facts of Quantum Dots and the state of research of preparation methods and surface architectures. Section 2.1 will summarize the historical development of the field of nanotechnology and give a short introduction on Quantum Dots. The electronic structure and resultant optical properties are discussed in Sect. 2.2. The importance of the surface chemistry on the Quantum Dots functionality and optical properties will be explained in Sect. 2.3. Section 2.3.1 outlines the fundamental preparation methods and state of the art techniques in aqueous media and in organic solvents. Nanostructures of other geometries including their optical and electronic characteristic will be described in Sect. 2.4.
Christin Rengers, Nikolai Gaponik, Alexander Eychmüller
Chapter 3. Polymeric Nanocarriers
Abstract
Control over the nanoscopic scale opens nearly endless opportunities for many scientific areas. In particular, polymeric nanoparticles offer the versatility to cover a wide range of mesoscopic properties for sophisticated applications. However, making and applying smart nanoparticles is inevitably linked to a deep understanding of the overall physico-chemical principle of their formation and their interaction with their surroundings.
Banu Iyisan, Katharina Landfester
Chapter 4. Stability of Nanoparticle Dispersions and Particle Agglomeration
Abstract
The stability of colloids is an important issue of colloid-based processes and formulations. Due to the large specific surface area, particles have a low thermodynamic stability and tend to agglomerate over time. Furthermore, the physicochemical properties of nanomaterials depend on the size, morphology, and surface state of the system, therefore in-depth characterization techniques are essential to predict the degree of variation in properties. In this chapter, the colloidal stability of nanoparticle dispersions as well as the basic stabilization mechanisms will be discussed both at the theoretical and at the experimental level. Relevant characterization methods will be presented and illustrated with suitable examples, including their limitations.
Kateryna Loza, Matthias Epple, Michael Maskos
Chapter 5. Nanoparticle Behaviour in Complex Media: Methods for Characterizing Physicochemical Properties, Evaluating Protein Corona Formation, and Implications for Biological Studies
Abstract
The transformation of nanoparticles (NPs) in physiological milieu is a dynamic phenomenon that is the subject of intense investigation. When introduced into the body, NPs can undergo a variety of changes, such as, protein adsorption, dissolution, agglomeration/aggregation, structural deformities and redox reactions. It is these changes that subsequently determine the uptake, bioavailability, translocation and fate of NPs, which ultimately determine their therapeutic efficiency, diagnostic efficacy or toxicity. This chapter will consider the colloidal interactions at the interface of NPs with the contents of biological milieu, the practical and theoretical considerations required to modify analytical and imaging techniques to detect and, if possible, quantify NPs in this complex environment, and the requirement for a highly interdisciplinary approach to understand the behaviour at the bio-nano interface.
Wye-Khay Fong, Thomas L. Moore, Sandor Balog, Dimitri Vanhecke, Laura Rodriguez-Lorenzo, Barbara Rothen-Rutishauser, Marco Lattuada, Alke Petri-Fink

Membrane Transfer, Cellular Uptake and Intracellular Fate: Mechanisms and Detection Methods

Frontmatter
Chapter 6. Nanoparticle-Cell Interactions: Overview of Uptake, Intracellular Fate and Induction of Cell Responses
Abstract
The range of engineered nanoparticles (NPs) designed as specific carriers for biomedical applications, e.g. cell targeting and drug delivery, is still on the raise and the question on how NPs are interacting with single cells and sub-cellular structures remains important. The delivery to the cell surface as well as the interaction of NPs with cellular structures with possible subsequent response is highly influenced by various parameters such as (a) the physico-chemical properties of the NPs, (b) the cell and tissue type and (c) the intracellular fate of the NPs in the various organelles including biopersistence, exocytosis and/or transfer to other cells. The aim of this book chapter is to discuss, on the basis of existing literature, the interaction of NPs with single cells including the intracellular fate and their interference with signaling pathways.
Barbara Rothen-Rutishauser, Joël Bourquin, Alke Petri-Fink
Chapter 7. Cellular and Non-cellular Barriers to Particle Transport Across the Lungs
Abstract
Compared to the human body’s other outer epithelia, like e.g. the skin and the GI tract, the lungs have the largest surface area. Moreover, the so called “air-blood-barrier” is extremely thin, but also very tight to fulfill its physiological function. This chapter discusses the lung as a biological barrier in the context of inhaled particles. This important function is provided by some specific cellular as well as non-cellular elements. How the lung copes with particles “after landing” is not only relevant regarding the risks of accidentally inhaled nanomaterials, but also for designing safe and efficient nanopharmaceuticals to be inhaled on purpose.
Nicole Schneider-Daum, Marius Hittinger, Xabier Murgia, Claus-Michael Lehr
Chapter 8. Cellular Uptake Mechanisms and Detection of Nanoparticle Uptake by Advanced Imaging Methods
Abstract
The specific mechanism, of uptake of a nanoparticle by a cell and the subcellular localisation are of great importance regarding the potential effect of the nanomaterial inside the cell. In order to study health risks and the potential of a nanoparticle to be used in biomedical applications, cellular internalization has to be investigated in great detail. This chapter highlights most relevant routes of nanoparticle uptake and includes current approaches for the visualization of particle uptake at the nano-level.
Kleanthis Fytianos, Fabian Blank, Loretta Müller
Chapter 9. Imaging Techniques for Probing Nanoparticles in Cells and Skin
Abstract
Imaging techniques for probing the interactions of nanoparticles with cells and skin are essential for a qualitative and quantitative understanding of uptake and penetration processes. A variety of important visualization techniques is reviewed for providing an overview on established and recently developed techniques. This includes optical microscopy, fluorescence microscopy, electron microscopy, Raman microscopy, optical near-field microscopy, X-ray microscopy, as well as recent and emerging developments in the field of spectromicroscopy.
Christina Graf, Eckart Rühl

Cellular Responses and Health Effects

Frontmatter
Chapter 10. Cellular Defense Mechanisms Following Nanomaterial Exposure: A Focus on Oxidative Stress and Cytotoxicity
Abstract
In response to the significant increase in nanotechnology over the last three decades, and the plethora of engineered nanomaterials (ENMs) now becoming available, understanding as to how nano-sized particles may impact upon human health has become a dominating area of research worldwide since the late 1990’s (Stone et al. in Environmental Health Perspectives, 2017) [1]. Whilst approaches constantly adapt to the increasing number and variety of ENMs produced for a plethora of different applications, the quantity of alternative physico-chemical characteristics, a key factor in the potential hazard of ENMs (Bouwmeester et al. in Nanotoxicology 5:1–11, 2011) [2], is further increasing in number and type.
Stephen J. Evans, Gareth J. Jenkins, Shareen H. Doak, Martin J. D. Clift
Chapter 11. Nanocarriers and Immune Cells
Abstract
Nanocarriers (NCs) have a high potential as target-specific drug-delivery system. Especially immune cells are a prime target in the nanoparticle-cell interaction. Uptake into the correct subtype of immune cells is crucial. Therefore uptake processes as well as intracellular processing is of utmost importance. The so-called protein corona heavily affects the interaction with immune cells which can decide the fate of the NC for degradation. On a wider perspective also nanoparticles which were not intentionally made for the transport of drugs get in contact with immune cells e.g. in the lungs. These immune cells are then trying to degrade these foreign materials.
Lorna Moll, Volker Mailänder
Chapter 12. Fate and Translocation of (Nano)Particulate Matter in the Gastrointestinal Tract
Abstract
Nanoscience has flourished with increasing use of nanoparticles in many products. The particles enter the environment and affect both biotic and abiotic components of the ecosystem. Via the water supply and the food chain, humans could be affected by ingesting those particles. In this chapter, we will discuss mechanisms by which nanoparticles or their constituents can be translocated from the gastrointestinal tract, what their fate may be and how relevant this is for human health.
Andreas Frey, Katrin Ramaker, Niels Röckendorf, Barbara Wollenberg, Ingmar Lautenschläger, Gabriella Gébel, Artur Giemsa, Markus Heine, Denise Bargheer, Peter Nielsen
Chapter 13. Interactions of Nanoparticles with Skin
Abstract
The interactions of nanoparticles with skin and skin cells are complex and depend on the nanoparticle type. The present work provides an overview on the interactions between solid nanoparticles including silica, titanium dioxide, and silver particulates and skin and skin cells on the basis of previous research results. Generally, nanoparticles applied to skin tend to remain on the skin surface and penetrate only into the upper layers of the stratum corneum and the follicular ducts. In very few cases, nanoparticles have been found in deeper skin layers, particularly if the skin barrier was previously disrupted. Increased nanoparticle penetration may result in biologically relevant effects, e.g. cytotoxic cellular effects induced by silver ions released from wound dressings incorporating silver nanoparticles.
Fanny Knorr, Alexa Patzelt, Martina Claudia Meinke, Anika Vogt, Ulrike Blume-Peytavi, Eckart Rühl, Jürgen Lademann
Backmatter
Metadata
Title
Biological Responses to Nanoscale Particles
Editors
Prof. Dr. Peter Gehr
Prof. Dr. Reinhard Zellner
Copyright Year
2019
Electronic ISBN
978-3-030-12461-8
Print ISBN
978-3-030-12460-1
DOI
https://doi.org/10.1007/978-3-030-12461-8

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