One aspect relates to a bioreactor and/or mixing container that includes an outer wall and a spectroscopy cell arranged in and/or on the outer wall. The spectroscopy cell includes a first optical area and a second optical area arranged opposite the first optical area. The first optical area and the second optical area can be set at at least two different distances from one another. A specimen-receiving area is located between the first optical area and the second optical area.

A malaria diagnosis and/or treatment apparatus can include an optical source and an acoustic detector in a single probe (sensor). The optical source can provide optical energy configured to produce transient vapor nanobubbles around malaria-specific nanoparticles, such as hemozoin in skin, blood and other tissues infected with malaria, but not in uninfected tissues. The acoustic detector can detect pressure pulses generated by the transient vapor nanobubbles. A malaria diagnosis and/or screening process can be based on using several metrics of the detector signal output, which include the time and amplitude parameters of such signal. This metrics characterize both active and residual forms of malaria disease and can be used in the clinical diagnostics of malaria and in mass screening of the malaria transmission.

An optical absorbance spectrometer includes a sample housing, a light source and a spectral sensor. The sample housing comprises at least two sample cells configured to hold a sample, respectively, and includes an optical waveguide which is configured to guide light from an input side, through the sample cells, to an output side. The light source is operable to emit broadband light and is connected to the input side to couple emitted light into the optical waveguide. The spectral sensor is connected to the output side and operable to receive light from the optical waveguide and to detect the intensity of the received light at multiple wavelengths.

A method for quantification of the amount of impurities in lactide. The method is characterized in that the quantification of the impurities is based on measurements performed on absorptions in the near Infra-Red region of the electromagnetic spectrum. With this method, small amounts of impurities like water, free-acid species or both can be determined online in a reaction mixture of lactide in a relatively simple manner. This allows a simple online monitoring of the production process of lactide.

A multiwavelength-light-radiating apparatus (1) includes: a light source (11) that radiates continuous light (Lc); a diffracting part (12) that diffracts the continuous light (Lc) into numerous monochromatic lights (Lm), whose wavelengths differ from one another, and emits the numerous monochromatic lights (Lm); numerous optical waveguides (2) that respectively transmit the numerous monochromatic lights (Lm) emitted from the diffracting part (12) from incident ends (21) to output ends (22) where the numerous monochromatic lights (Lm) are respectively emitted; and a sample-placement part (3) that holds numerous samples such that the output ends (22) of the numerous optical waveguides (2) respectively oppose the samples. The numerous monochromatic irradiation lights, whose wavelengths differ from one another, are arranged to be radiated simultaneously onto the numerous samples, one light per sample.

An apparatus and method for an alignment cell are described herein. One apparatus includes a delivery fiber and a delivery lens coupled to an optical bench, a mirror to receive light from the delivery fiber through the delivery lens, wherein the received light is directed by the mirror to an ion trap on the trap surface, and a collection fiber coupled to the optical bench to receive light fluoresced from an ion in the ion trap.

The present invention relates to a method for quantification of the amount of lactide in a lactide-based polymeric matrix by means of Infra Red Spectroscopy measurement. According to the invention the quantification is based on measurements performed on absorptions in the near Infra Red region of the electromagnetic spectrum. The invented method allows a rapid, easy and cheap quantification of lactide in a polymeric matrix, especially in PLA.

An apparatus and method for an alignment cell are described herein. One apparatus includes a delivery fiber and a delivery lens coupled to an optical bench, a mirror to receive light from the delivery fiber through the delivery lens, wherein the received light is directed by the mirror to an ion trap on the trap surface, and a collection fiber coupled to the optical bench to receive light fluoresced from an ion in the ion trap.

The disclosed technology includes a planar device for performing multiple biochemical assays at the same time, or nearly the same time. Each assay may include a biosample including a biochemical, enzyme, DNA, and/or any other biochemical or biological sample. Each assay may include one or more tags including dyes and/or other chemicals/reagents whose optical characteristics change based on chemical characteristics of the biological sample being tested. Each assay may be optically pumped to cause one or more of luminescence, phosphorescence, or fluorescence of the assay that may be detected by one or more optical detectors. For example, an assay may include two tags and a biosample. Each tag may be pumped by different wavelengths of light and may produce different wavelengths of light that is filtered and detected by one or more detectors. The pump wavelengths may be different from one another and different from the produced wavelengths.

A method of optical analysis comprises receiving light at an optical spectrometer module from a light source, distributing the received light into two or more light beams with a light distribution component of the optical spectrometer module, concurrently exposing each of a reference and one or more test samples to one of the two or more light beams, and concurrently measuring a property of the light associated with each of the reference sample and one or more test samples with a corresponding detector.