An open-source combined atomic force microscope and optical microscope for mechanobiology studies.

Atomic Force Microscopy (AFM) has become the gold standard tool for measuring mechanical properties of biological samples including proteins, single cells and tissues. However, investment in this specialized equipment and gaining expertise in its operation are significant obstacles for non-experts looking to adopt this technique. To address this, we have designed an AFM based mechanical measurement system for measuring cell mechanical properties which is combined with a custom inverted fluorescence microscope which can be used for characterizing mechanosensitive responses.

Quantifying cytoskeletal organization from optical microscopy data.

The actin cytoskeleton plays a pivotal role in a broad range of physiological processes including directing cell shape and subcellular organization, determining cell mechanical properties, and sensing and transducing mechanical forces. The versatility of the actin cytoskeleton arises from the ability of actin filaments to assemble into higher order structures through their interaction with a vast set of regulatory proteins. Actin filaments assemble into bundles, meshes, and networks, where different combinations of these structures fulfill specific functional roles.

Empathy and social-emotional learning: pitfalls and touchstones for school-based programs.

This chapter identifies three common pitfalls in the use of the concept of empathy in formal social-emotional learning interventions: (1) not distinguishing between affective and cognitive empathy ("equivocation"); (2) overestimating the role of the imagination in empathizing ("Piaget's fallacy"); and (3) not accommodating the developmental and psychological independence of affective and cognitive empathizing ("the fallacy of the Golden Rule"). Using case studies of existing programs, the chapter offers guidance on how to avoid these errors in program design.