Modulated optical nanoprobes (MOONs) are microscopic (spherical and aspherical) fluorescent particles
designed to emit varying intensities of light in a manner that depends on particle orientation. MOONs can be
prepared over a broad size range, allowing them to be tailored to applications including intracellular sensors,
using submicrometer MOONs, and immunoassays, using 1−10 μm MOONs. When particle orientation is
controlled remotely, using magnetic fields (MagMOONs), it allows modulation of fluorescence intensity in
a selected temporal pattern. In the absence of external fields, or material that responds to external fields, the
particles tumble erratically due to Brownian thermal forces (Brownian MOONs). These erratic changes in
orientation cause the MOONs to blink. The temporal pattern of blinking reveals information about the local
rheological environment and any forces and torques acting on the MOONs, including biomechanical forces
as observed in macrophages. The rotational diffusion rate of Brownian MOONs is inversely proportional to
the particle volume and hydrodynamic shape factor, for constant temperature and viscosity. Changes in the
particle volume and shape due to binding, deformation, or aggregation can be studied using the temporal
time pattern from the probes. The small size and the large number of MOONs that can be viewed simultaneously
provide local measurements of physical properties, in both homogeneous and inhomogeneous media, as well
as global statistical ensemble properties.
In this work, sensing magnetic microparticles were used to probe both the local pH and the viscosity-dependent nonlinear rotational behavior of the particles. The latter resulted from a critical transition marking a driven particle's crossover from phase-locking to phase-slipping with an externally rotating magnetic field, i.e., a sudden breakdown in its linear response that can be used to measure a variety of physical quantities. The transition from simple rotation to wobbling is described both theoretically and experimentally. The ability to measure both chemical and physical properties of a system could enable simultaneous monitoring of chemical and physical interactions in biological or other complex fluid microsystems.
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