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Objective:To evaluate the excitation and identification of parathyroid autofluorescence in thyroid surgery by a fluorescence laparoscopic system.Methods:The clinical data of 6 patients with papillary thyroid carcinoma who underwent Laparoscopic thyroid surgery at the Second Affiliated Hospital of Guangxi Medical University from Mar. 2022 to Apr. 2022 were collected. The autofluorescence of the parathyroid glands was detected and identified by the OptoMedic fluorescence laparoscopic system during the operation. A rapid frozen sections pathological examination of possible parathyroid tissue with autofluorescence was performed to determine whether it was parathyroid tissue.Results:Parathyroid autofluorescence with different intensities was visualized intraoperatively in all 6 patients, and it was confirmed as parathyroid tissue by rapid frozen pathological section.Conclusions:The parathyroid gland has a unique autofluorescence feature. Using this feature to identify, locate and protect the parathyroid gland during surgery can help reduce the complications of parathyroid injury.
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ABSTRACT@#Dental caries is a commonly progressive disease that proceeds through various degrees of severity that a dentist can detect. The aims of the in vivo study were to assess the accuracy of the individual model (near-infrared light transillumination [NILT] device, visual and radiographic examinations) in detecting occlusal caries, and to evaluate the performance of visual and NILT device combination for occlusal caries detection in deciding the treatment options. Fifty-two non-cavitated occlusal surfaces from 16 patients were assessed with three different diagnostic devices in random order. Identified lesions were prepared and validated. Logistic regression analysis was performed for each method. The sensitivity and specificity values for each method and the combined models were statistically measured using RStudio version 0.97.551. At the enamel level, visual detection was the most sensitive method (0.88), while NILT was the most specific (0.93). NILT scored the highest for sensitivity (0.93) at the dentine level and visual detection scored the highest for specificity (0.88). Visual detection + NILT model was significantly better (p = 0.04) compared to visual detection or NILT alone (df = 1). The visual-NILT combination is a superior model in detecting occlusal caries on permanent teeth. The model provided surplus value in caries detection hence improving the treatment decision-making in occlusal surfaces.
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Dental Caries Activity TestsABSTRACT
The use of non-invasive blood glucose detection techniques can help diabetic patients to alleviate the pain of intrusive detection, reduce the cost of detection, and achieve real-time monitoring and effective control of blood glucose. Given the existing limitations of the minimally invasive or invasive blood glucose detection methods, such as low detection accuracy, high cost and complex operation, and the laser source's wavelength and cost, this paper, based on the non-invasive blood glucose detector developed by the research group, designs a non-invasive blood glucose detection method. It is founded on dual-wavelength near-infrared light diffuse reflection by using the 1 550 nm near-infrared light as measuring light to collect blood glucose information and the 1 310 nm near-infrared light as reference light to remove the effects of water molecules in the blood. Fourteen volunteers were recruited for
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Humans , Blood Glucose , Diabetes Mellitus , Nonlinear DynamicsABSTRACT
OBJECTIVE: To establish a methaod for content determination of doxorubicin hydrochloride nano-liposomes, and to optimize its preparation technology. METHODS: The contents of doxorubicin hydrochloride nano-liposomes was determined by UV spectrophotometry. The membrane dispersion method was used to prepare doxorubicin hydrochloride nano-liposomes. Using particle size, encapsulation efficiency and drug-loading amount as indexes, the weight ratio of phospholipid to drug (mg/mg), the weight ratio of phospholipid to cholesterol (mg/mg) and ultrasonic time (min) as factors, central composite design-response surface methodology was used to optimize the preparation technology. The photothermal conversion effect of doxorubicin hydrochloride nano-liposomes was investigated by near infrared irradiation. RESULTS: The linear range of doxorubicin hydrochloride were 1.01-16.16 μg/mL(r=0.999 7); precision, stability and reproducibility tests were all in line with the requirments of Chinese Pharmacopoeia. The optimal preparation technology included that the weight ratio of phospholipid to drug was 13.30 ∶ 1(mg/mg); the weight ratio of phospholipid to cholesterol was 4.09 ∶ 1 (mg/mg); the ultrasonic time was 10 min. Under this technology, the particle size and drug-loading amount of doxorubicin hydrochloride nano-liposomes were (200.5±25.1) nm and (11.02±0.20)%, relative errors of which to predicted value (196.3 nm, 10.68%) were 1.82% and 1.63%. The consistency between measured value and predicted value was good. Doxorubicin hydrochloride nano-liposomes exhibited concentration- dependent and time-dependent photothermal conversion characteristics under near infrared irradiation at 808 nm. CONCLUSIONS: Established method is simple and good accuracy. The optimized preparation technology is simple and feasible.
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Objective • To engineer a light-induced size-switchable (large to small) nanosystem for doxorubicin (DOX) delivery and characterize its light-induced size change and cytotoxicity. Methods • The poly(ethylene glycol)-polylactide nanoparticles loading DOX (PEG-PLA-DOX) were fabricated with the dropwise addition method. Then the nanoparticles were encapsulated into the inner cavity of liposome (LP), and a photosensitizer (verteporfin, VP) was loaded in the bilayers of the LP to engineer the near-infrared light-sensitive core-shell nanoparticles (PEG-PLA-DOX@LP). The morphology of the nanoparticles was observed under a transmission electron microscope. Dynamic light scattering was used to examine the particle size at each stage. The size-switchable property of the nanoparticles and its influence on viability of murine melanoma B16F10 cells under near-infrared light were evaluated. The stability of the nanoparticles was also investigated. Results • PEG-PLA-DOX@LP, the light-sensitive nanoparticles, were successfully developed. The nanoparticles had a particle size of (194.83±5.70) nm and Zeta potential of (-1.43±0.32) mV. The drug loading was 2.82% for DOX, and 1.16% for VP. The small-sized PEG-PLA-DOX [(37.42±8.67) nm] was quickly released from the nanoparticles upon light for enhanced toxicity to B16F10 murine melanoma cells. Conclusion • The particle size of the novel DOX delivery nanosystem rapidly changes from large size to small size upon the irradiation of near-infrared light, and thus the cytotoxic effect on tumor cells can be enhanced.
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Objective · To engineer a light-induced size-switchable (large to small) nanosystem for doxorubicin (DOX) delivery and characterize its light-induced size change and cytotoxicity. Methods · The poly (ethylene glycol) -polylactide nanoparticles loading DOX (PEG-PLA-DOX) were fabricated with the dropwise addition method. Then the nanoparticles were encapsulated into the inner cavity of liposome (LP), and a photosensitizer (verteporfin, VP) was loaded in the bilayers of the LP to engineer the near-infrared light-sensitive core-shell nanoparticles (PEG-PLA-DOX@LP). The morphology of the nanoparticles was observed under a transmission electron microscope. Dynamic light scattering was used to examine the particle size at each stage. The size-switchable property of the nanoparticles and its influence on viability of murine melanoma B16F10 cells under near-infrared light were evaluated. The stability of the nanoparticles was also investigated. Results · PEG-PLA-DOX@LP, the light-sensitive nanoparticles, were successfully developed. The nanoparticles had a particle size of (194.83±5.70) nm and Zeta potential of (-1.43±0.32) mV. The drug loading was 2.82% for DOX, and 1.16% for VP. The small-sized PEG-PLA-DOX [ (37.42±8.67) nm] was quickly released from the nanoparticles upon light for enhanced toxicity to B16F10 murine melanoma cells. Conclusion · The particle size of the novel DOX delivery nanosystem rapidly changes from large size to small size upon the irradiation of near-infrared light, and thus the cytotoxic effect on tumor cells can be enhanced.
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Photodynamic therapy (PDT) is an emerging, non-invasive therapeutic strategy that involves photosensitizer (PS) drugs and external light for the treatment of diseases. Despite the great progress in PS-mediated PDT, their clinical applications are still hampered by poor water solubility and tissue/cell specificity of conventional PS drugs. Therefore, great efforts have been made towards the development of nanomaterials that can tackle fundamental challenges in conventional PS drug-mediated PDT for cancer treatment. This review highlights recent advances in the development of nano-platforms, in which various functionalized organic and inorganic nanomaterials are integrated with PS drugs, for significantly enhanced efficacy and tumor-selectivity of PDT.
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Objective To prepare titanium dioxide (TiO2 ) nanoparticles with good near-infrared light and study the loading and release of doxorubicin. Methods The Sm doped TiO2 nanoparticles (Sm-TiO2 ) were synthesized using a modified solvothermal reaction and then observed with transmission electron microscope. The fluorescence spectrum, doxorubicin loading capacity and release profile were also determined. Results The obtained Sm-TiO2 nanoparticles with the length from 100-200 nm were fusiform and well dispersed. The emission wavelength was 640-670 nm. The drug loading capacity in water was 11. 5% . DOX in vitro was pH sensitive to release. Conclusion Sm-TiO2 nanoparticles have good near-infrared light, high drug loading capacity and controllable drug release are obtained and should be studied further more as a novel carrier.
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This study aimed to examine the effect of linear polarized near-infrared light (PL) irradiation on the recovery of isokinetic muscle exertion and subjective fatigue sensation in muscles after strenuous exercise. Eighteen healthy college students participated in the experiment for all conditions of meridian point irradiation (MPI), femurs muscles irradiation (FMI), and no irradiation (NI) . They all took isokinetic knee extension and flexion tests (IK test) before and after strenuous exercise up to exhaustion. Each subject was irradiated at the meridian point or in femurs muscles after the second IK test. The third IK test was carried out after ten-minutes rest.<BR>The effects of PL irradiation were confirmed on the recovery rate of muscle fatigue in knee extension motion with high load intensity (PT 60 d/s and TW 60 d/s : MPI, FMI> NI, p<0.05 16.2%, 13.4%>8.5%, and 16.1%, 14.1%>8.3%, respectively) . Also, in flexion motion, significant differences in the recovery-degree for each condition were found, and the effect of PL irradiation was suggested. There was no difference between the effect of MPI and FMI. In addition, subjective fatigue sensation in muscles after rest decreased significantly in MPI as compared with NI (MPI: 52.1%>NI : 36.6%, p<0.05) . From the above, it was suggested that PL irradiation is effective on recovery in muscle fatigue after strenuous exercise regardless of irradiation conditions, MPI or FMI.