Review Articles in 2013

Therapeutics based on small interfering RNA (siRNA), which in principle are able to reversibly silence any gene of interest, are under development for the treatment of cancers, viral infections, hereditary disorders and many other diseases. This Review discusses the biological challenges that siRNA delivery materials aim to overcome, as well as the most clinically advanced classes of siRNA delivery systems, including cyclodextrin–polymer nanoparticles, lipid nanoparticles and siRNA conjugates.

The clinical application of vaccines has expanded from infectious diseases to cancer, enhancing our vision of how the immune system can be used to prevent and treat disease. This Review highlights recent developments, clinical successes and future challenges in the design of prophylactic, therapeutic and tolerance-inducing synthetic vaccines with inspiration from the natural immune system.

The use of macroscopic depots to deliver drugs — including small molecules, protein and cells — at the desired treatment site by using a carrier whose physical and chemical properties control the presentation of the drug increases drug effectiveness and reduces side effects. This Review discusses the advantages of macroscopic drug-delivery systems, the associated mechanisms of spatiotemporal control of drug presentation, and the design and use of multifunctional macroscopic drug-delivery devices.

Nanoscale materials that deliver drugs in response to specific stimuli offer enhanced control of the drugs' release profile and distribution. This Review provides a comprehensive discussion of progress during the past five years in the design of nanoscale systems that can respond to exogenous stimuli such as temperature or variations in light or magnetic-field intensities, or to endogenous stimuli such as redox gradients or changes in pH or enzyme concentration.

Semiconducting quantum dots are considered candidate materials for realizing spin-based quantum computation devices. This Review examines the main results obtained over the past decade concerning the so-called central spin problem, namely the interaction between a single electronic spin or hole with the surrounding nuclear environment.

Single spins trapped in self-assembled quantum dots present rich opportunities for studying their quantum mechanical properties. This Review surveys their optical properties, and the techniques for initializing, manipulating and reading out single spin qubits in these structures.

High-throughput computational approaches combining thermodynamic and electronic-structure methods with data mining and database construction are increasingly used to analyse huge amounts of data for the discovery and design of new materials. This Review provides an overall perspective of the field for a broad range of materials, and discusses upcoming challenges and opportunities.