Keywordssingle-cell analysis; microfluidics; constriction channel; mechanical property characterization; high throughput; fiber-based optofluidics; injection molding; optical trapping; hollow core fiber enhanced Raman spectroscopy; in-plane liquid gradient index (L-GRIN) microlens; optofluidics waveguide; adjustable focal length; convection-diffusion process; beam focusing; finite element method; microfluidics; rat bone marrow stromal cell; stem cell stimulation; fluid flow shear stress; neuronal cell differentiation; wet etching; potassium hydroxide; Si; pattern; optical detection; microfluidics; immunosensing; liquid ARROW; optofluidics; microfluidics; optical sensors; integrated silicon technology; Fabry-Pérot cavity; optical resonator; optofluidic sensor; on-chip refractometer; refractive index measurement; lab-on-a-chip; optofluidic device; microfluidics; microflow cytometer; microfabrication; single-cell analysis; microfluidics; optofluidics; optical stretcher; mechanical properties characterization
