Single-particle optical trapping interferometry (OTI) allows us to detect the Brownian motion of a tracer bead immersed in a complex fluid with nanometric resolution and in the microsecond time-scale. By OTI, we study suspensions composed of filamentous actin (F-actin), a classic example of a semiflexible polymer, using two different kind of tracers: chemically-inert melamine resin and polystyrene depleted particles. One-particle microrheology permits to investigate the local fluctuations of the polymers in the network, but under the condition of a previous knowledge of the F-actin characteristic lengths in relation with the radius of the probes. In this work, we focus on the power-law behavior of the skeletal thin filament, composed by tropomyosin (Tm) and troponin (Tn) coupled to F-actin, which has a role in the muscle contraction by its interaction with myosin. We find that the elastic modulus for the F-actin/Tm/Tn complex in the presence of Ca$^{2+}$ is constant until the limit of high frequencies, and that the calculated values of the power-law exponent are less dispersed than in F-actin alone, which we interpret as a micro-measurement of the filament stabilization.
10 pages, 7 figures. Submitted to Physical Review E