The goal of this chapter is to provide a broad overview of properties and biomedical applications of magnetic nanoparticles. Subsequent chapters will elucidate the fundamental magnetic nanoparticle physics and chemistry and explore important biomedical applications. This brief introduction aims to place this information found in the remainder of this book into a broader context.

A grand challenge in biomedical sciences is to detect and control the location and time of biochemical and biomechanical processes. For example, in treating cancer, the challenge is to direct the therapeutic to the tumor while minimizing damage to normal tissue, which can in principle be facilitated by targeting the drug and/or triggering the drug release. Similarly, the ability to switch cellular signaling on and off and detect this activity is critical for understanding and ultimately controlling cellular activity. A variety of external triggers are available including light (Fomina, Sankaranarayanan, and Almutairi 2012, Deisseroth 2011), ultrasound (Hernot and Klibanov 2008, Deckers and Moonen 2010, Mitragotri 2005), chemical signals (e.g. pH [Huh et al. 2012] or enzymes [De La Rica, Aili, and Stevens 2012]), electrical current or voltage (Murdan 2003), temperature changes (Schmaljohann 2006), magnetic fields (Dobson 2008, Pankhurst et al. 2003), and combinations thereof. Magnetism is an especially useful handle for controlling and detecting stimuli-responsive materials because magnetic fields are easily generated at a distance (using either permanent magnets or electromagnets) and biological tissue is essentially transparent to these magnetic fields. This provides a unique advantage to magnetic sensing and stimulation compared to other methods.

In general, nanoparticles become interesting and useful when properties emerge that are specific to their size and shape and/or their composition is chosen to have multiple properties that work together synergistically. Magnetic nanoparticles are quintessential examples of materials with emergent properties. The magnetic moment of magnetic particles arises because interactions between atoms in ferromagnetic or ferromagnetic crystal cause the spin from their valence electrons to align together providing very large magnetic moments compared to the same number of atoms with randomly aligned spins (e.g., in a dissolved iron salt). This increased net magnetic moment of the particle leads to dramatically enhanced alignment energies and quite different behavior in response to applied magnetic fields. As an analogy, it is far easier to throw a snowball than the same amount of water dispersed in a puddle (or worse yet, the same number of water molecules as vapor in the air) because in a snowball the water molecules are mechanically linked together so that the position of one depends on the position of its neighbors. Although this analogy should not be taken too literally (atomic spin is not the same as atomic position and the coupling mechanisms are different too), it illustrates how the behavior of previously independent atoms changes dramatically when they are coupled together.

Following this introductory chapter, the book is divided into two sections. The first section is on fundamentals for working with magnetic particles. The second covers practical aspects of nanoparticle synthesis and biomedical applications. Each chapter is written by specialists in their field.