Astrocytes are cells of the central nervous system (CNS). Although astrocytes are less popular than neurons, it is worth emphasizing that they are an integral part of neuronal circuits. According to the prevalent view, neurons are the CNS cells that carry the complex computations subserving coding, complex behaviors, and higher brain functions. In this perspective article we ask whether, beyond providing metabolic and homeostatic support to neurons, astrocytes are fundamental to CNS coding. If they do, specific questions are whether there are niche(s) in CNS coding that would particularly profit from astrocyte idiosyncrasies, and whether the impressive techniques and theoretical armamentarium deployed for neurons could be used—and are sufficient—to unravel possible astrocyte-based coding. Pioneering theoreticians in neuroscience argued that anatomical features provide valuable insights about how the CNS operates because ‘the nervous system is a product of evolution, not design. The computational solutions evolved by nature may be unlike those that humans would invent, if only because evolutionary changes are always made within the context of a design and architecture that already is in place’. Thus, we reason that the unique anatomical arrangement between astrocytes and neurons might be part of computational solutions refined by evolution that have made the brain a highly efficient task performing system, for the brain is capable to carry out operations at a low energy expense and with a high speed unmatched by computers. In this article we explore the possible operations performed by astrocytes to efficiently integrate information from different neurons, we explain the implications of these tasks in higher brain functions, as well an in the modeling of neural circuits with artificial intelligence, and we present a roadmap to advance knowledge of astrocytes as building blocks of neural circuits.

Beyond their excellent photovoltaic performance, hybrid organic–inorganic metal halide perovskites exhibit unique physical phenomena and emerging functionalities prompted by the interplay between organic and inorganic components. The discovery of intrinsic quantum confinement effects in the form of oscillations in the optical absorption of formamidinium lead triiodide (FAPbI₃) thin films (see Fig. 1) is a vivid example of the surprising physical properties of these hybrid materials. The relevance of this work resides in that the discrete features can be interpreted as manifestation of intrinsic quantum confinement effects, unintentionally occurring in FAPbI₃ thin films. As illustrated in the inset to Fig. 1, quantum confinement acts on the electronic band structure either by discretization of the energy spectrum due to full restriction of the movement of a particle confined in deep wells (infinite potential barrier model), or by leading to formation of mini-bands, in case the (finite) confining potential exhibits periodicity. These changes in the electronic landscape lead to peaks in the joint density of states, as probed in absorption.

Writing in Nature ‘News & Views’, I make an important contribution to the interpretation of the observed quantum oscillations. I provide a simple but strong argument against ferroelectricity as the origin of such phenomenon. The oscillations are still apparent in the temperature range of the cubic phase of FAPbI₃, for which ferroelectric order is strictly forbidden by symmetry. I also reinforce the interpretation based on phase polymorphism. I propose that a combination of strain build-up, changes in the surface energy and chemical bonding between perovskite and substrate can lead to quantum confinement by unintentional formation of inclusions of the perovskite phase surrounded by thin layers of a wide-gap, non-perovskitic phase. Understanding the mechanisms that lead to the quantum oscillations may suggest new routes for manipulating the electronic band structure of hybrid perovskites at the nanoscale to enhance optoelectronic performance by exploiting the confinement-induced discretization of the energy spectrum.