Optical diffraction tomography is an emerging label-free microscopic technique with its capability of label-free, quantitative, and rapid imaging of biological samples. In this work, we present the imaging and analysis of a living diatom Cylindrotheca sp. in seawater without using any pretreatment such as fluorescence staining. The 3D refractive index (RI) of a living diatom cell was measured, to which quantitative image analysis was perform to investigate subcellular parts of the diatom. Each part of the cell was well distinguished as RI values and distributions. From the analysis, RI values of frustules, protoplasm, vacuole, and chloroplast were estimated to be in the range of 1.
Herein, we propose a convenient method to enable pretreatment of target objects using digital holographic microscopy (DHM). As a test sample, we used diatom frustules (Nitzschia sp.) as the target objects. In the generally used sample preparation method, the frustule suspension is added dropwise onto a glass substrate or into a glass chamber. While our work confirms good observation of purified frustules using the typical sample preparation method, we also demonstrate a new procedure to observe unseparated structures of frustules prepared by baking them on a mica surface. The baked frustules on the mica surface were transferred to a glass chamber with 1% sodium dodecyl sulfate solution. In this manner, the unseparated structures of the diatom frustules were clearly observed. Furthermore, metal-coated frustules prepared by sputtering onto them on a mica surface were also clearly observed using the same procedure. Our method can be applied for the observation of any target object that is pretreated on a solid surface. We expect our proposed method to be a basis for establishing DHM techniques for microscopic observations of biomaterials.
In this study, two biomolecule solutions were distinguished
using
the capacity difference in the near-infrared photoluminescence (PL)
of single-walled carbon nanotubes (SWNTs). Biosensing techniques using
sensitive responses of SWNTs have been intensively studied. When a
small amount of an oxidant or reductant solution was injected into
the SWNT suspensions, the PL intensity of the SWNTs is significantly
changed. However, distinguishing between different molecules remains
challenging. In this study, we comparably injected saponin and banana
solutions, which are known antioxidant chemicals, into an SWNT suspension.
The SWNTs were solubilized by wrapping them with DNA molecules. The
results show that 69.1 and 155.2% increases of PL intensities of SWNTs
were observed after injection of 20 and 59 μg/mL saponin solutions,
respectively. Subsequently, the increase in PL was saturated. With
the banana solution, 18.1 and 175.4% increases in PL intensities were
observed with 20 and 59 μg/mL banana solutions, respectively.
Based on these results, the two antioxidant molecules could be distinguished
based on the different PL responses of the SWNTs. In addition, the
much higher saturated PL intensities observed with the banana solution
suggests that the banana solution increased the capacity of the PL
increase for the same SWNT suspension. These results provide helpful
information for establishing biosensing applications of SWNTs, particularly
for distinguishing chemicals.
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