Integrated self-referencing single shot digital holographic microscope and optical tweezer

• Published in: Light: advanced manufacturing Vol. 3; no. 3; pp. 1 - 13
• Main Authors: Utadiya, Subhash, Joshi, Sachin, Patel, Nimit, Patel, Chetna, Joglekar, Mugdha, Cahhniwal, Vani, O’Connor, Timothy, Javidi, Bahram, Anand, Arun
• Format: Journal Article
• Language: English
• Published: Light Publishing Group 2022
• Subjects: digital holographic microscopy; optical tweezers; quantitative phase imaging; red blood cells
• ISSN: 2831-4093; 2689-9620
• DOI: 10.37188/lam.2022.037

Digital holographic microscopy is a single-shot technique for quantitative phase imaging of samples, yielding thickness profiles of phase objects. It provides sample features based on their morphology, leading to their classification and identification. However, observing samples, especially cells, in fluids using holographic microscopes is difficult without immobilizing the object. Optical tweezers can be used for sample immobilization in fluids. The present manuscript provides an overview of our ongoing work on the development of a compact, low-cost microscopy system for digital holographic imaging of optically trapped samples. Integration of digital holographic microscopy system with tweezers is realized by using the optical pickup unit extracted from DVD burners to trap microsamples, which are then holographically imaged using a highly compact self-referencing interferometer along with a low-cost, in-house developed quadrant photodiode, providing morphological and spectral information of trapped particles. The developed integrated module was tested using polystyrene microspheres as well as human erythrocytes. The investigated system offers a multitude of sample features, including physical and mechanical parameters and corner frequency information of the sample. These features were used for sample classification. The proposed technique has vast potential in opening up new avenues for low-cost, digital holographic imaging and analysis of immobilized samples in fluids and their classification.