Optical transmission sample holder and analysis, particularly for hemoglobin

We claim: 1. A device for an optical transmission analysis of sample by a light, comprising: a first plate, a second plate, and a light-guiding spacer (LGS), wherein: the first plate and the second plate are movable relative to each other to form different configurations, including an open configuration and a closed configuration; in the closed configuration, the first and second plates are configured to compress a sample into a layer between the first and second plates, and each of the first and second plates has a sample contact area contacting the sample; in the closed configuration, the light-guiding spacer is sandwiched between the first and second plates and in direct contact with the first and second plates to form a sample region and a reference region; wherein the sample region is a region where the light is capable of transmitting through the first plate, the sample, and the second plate, wherein the sample region does not have the LGS; and the reference region is a region where the light is capable of transmitting through the first plate, the light-guiding spacer, and the second plate, without going through the sample; and wherein the lateral cross-section of the LGS is larger than a wavelength of the light. 2. An apparatus for sample analysis, comprising: the device of claim 1 , a light source, a camera, and an adaptor, wherein: (i) the light source is configured to emit a light in a wavelength range that is capable of going through the reference region and the sample region; and (ii) the camera is configured to image the reference region and the sampling region. 3. A system for analyzing a sample, comprising: (i) the apparatus of claim 2 ; and (ii) a non-transitory computer readable medium embodying an algorithm comprising a step of analyzing the light through the reference region. 4. The system of claim 3 , wherein the algorithm comprises a machine learning. 5. The system of claim 3 , wherein the algorithm comprises a machine learning and a computation vision. 6. A method for an analysis of a sample containing an analyte using a light, comprising: (a) providing the system of claim 3 ; (b) depositing the sample between the first and second plates; and (c) determining a property of an analyte in the sample using the system of claim 3 . 7. The method of claim 6 , wherein the determination comprises a step of comparing a light transmission from the sampling region and the reference region. 8. The method of claim 6 , wherein the analyte is hemoglobin. 9. The device of claim 1 , wherein in the open configuration, the first and second plates are either partially or completely separated apart, and the spacing between the first and second plates is not regulated by the light-guiding spacers; and wherein in the closed configuration, the first and second plates are capable of compressing at least a part of the sample into a layer of uniform thickness, wherein the layer is confined by the sample contact areas of the first and second plates, and the thickness of the layer is regulated by the light-guiding spacer; and wherein in the closed configuration: (a) the light-guiding spacer in the sample contact area has its top surface in direct contact with one of the first and second plates, and the light-guiding spacer and the regions of the first and second plates above and below the light-guiding spacer define the reference region wherein the reference region is transparent to light within a wavelength range, and (b) at least one region in the sample contact area on the first plate and its corresponding region on the second plate are not occupied by the light-guiding spacer, which defines the sample region that is transparent to the light within the same wavelength range. 10. The device of claim 1 , wherein the reference region is surrounded by the sample region in the closed configuration. 11. The system of claim 3 , further comprising a processor.