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               Preparation of Self-Assembled π-Conjugated Polymer Microlaser Sensor and Its

                    Application in Detection of Acetone in Exhaled Gas of Diabetes Patients


                                                  GUO Xiaohui, FAN Yingwei

                                             (Luohe Medical College, Luohe 462002, China)
                  Abstract: Given that most existing blood glucose detection methods are invasive tests, the study mentioned by the title
              was conducted. Poly[2-methoxy-5-(2-ethylhexoxy)-1,4-phenylacetylene] (MEH-PPV) microspheres were prepared by the lotion-

              solvent evaporation method, which had perfect circular boundaries and super smooth surfaces, emitting uniform red fluorescence at
              330-380  nm  of  UV  excitation  wavelength,  with  emission  peaks  at  601  nm  and  638  nm.  By  changing  the  diameter  of  the
              microspheres excited by femtosecond laser at a pump power density of 160 nJ · cm  −2 , it was found that the effective refractive
              index (2. 04) of the microspheres was consistent with the intrinsic refractive index (1. 85) of the MEH-PPV polymer, indicating
              that laser modulation was caused by the resonance of the spherical whispering gallery cavity, which was beneficial for sensing
              very small changes at the resonance wavelength with the sensor. Using a self-built gas sensor to detect different volume fractions
              of acetone gas, the volume fraction of acetone gas within (2. 0-4. 0)×10  − 5  was linearly related to the change Δλ s   in laser
              wavelength before and after exposure to acetone gas (the laser wavelength λ 0  before exposure was about 621 nm), with detection
              limit of 9. 0×10 −8  (volume fraction), and the sensor had good selectivity for acetone. The proposed method was used to analyze
                                                            −6
              the exhaled gas of simulated diabetes patients containing 2×10  (volume fraction, the same below) acetone. The detected amount
              of acetone was 4. 05 times of that in the 2×10  −6   acetone gas, and 78% of that in the healthy individuals exhale gas. It was shown
              that the sensor could provide a new method for non-invasive diagnosis of diabetes mellitus.
                  Keywords: π-conjugated polymer microsphere; microlaser sensor; acetone; diabetes; non-invasive testing







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