Intravital Imaging Reveals the Ameliorating Effect of Colchicine in a Photothrombotic Stroke Model via Inhibition of Neutrophil Recruitment.

Although post-stroke neutrophil recruitment is known to be deleterious to neural tissues in the peri-infarct area, the precise behavior of recruited neutrophils remains elusive. In this study, potential therapeutic agents for modifying neutrophil behavior in the peri-infarct area were explored through intravital imaging of an experimental stroke mouse model. By applying in vivo 2-photon imaging to study a tightly controlled photothrombotic stroke mouse model, we established a highly sensitive and reproducible method for investigating the temporal dynamics of ischemic brain lesions. Taking advantage of this system, we revealed that neutrophil depletion by a neutrophil-specific antibody ameliorated the expansion of the infarct area, confirming the deleterious effect of neutrophils in the peri-infarct cortex. To identify neutrophil-targeted therapeutic approaches, we screened various agents and found that colchicine and an anti-P-selectin antibody were the most effective in inhibiting neutrophil attachment to the vessel wall in the early phase (6 h post-infarction). Interestingly, further investigation in the later phase (16 h post-infarction) revealed that colchicine potently inhibited neutrophil infiltration into the peri-infarct cortex; however, the anti-P-selectin antibody did not. Subsequent analysis revealed that the effect of the anti-P-selectin antibody against neutrophil attachment to the vessel wall was transient and thus insufficient for mitigating neutrophil infiltration. Finally, we revealed that colchicine treatment effectively ameliorated infarct expansion. In conclusion, we have established an intravital strategy to directly investigate pathophysiology in the ischemic border zone, and found that colchicine administration in the acute phase of ischemic stroke is a potential novel therapeutic strategy.

Changes in Crystal Structure and Accelerated Hydrolytic Degradation of Polylactic Acid in High Humidity.

Highly crystallized polylactic acid (PLA) is suitable for industrial applications due to its stiffness, heat resistance, and dimensional stability. However, crystal lamellae in PLA products might delay PLA decomposition in the environment. This study clarifies how the initial crystal structure influences the hydrolytic degradation of PLA under accelerated conditions. Crystallized PLA was prepared by annealing amorphous PLA at a specific temperature under reduced pressure. Specimens with varied crystal structure were kept at 70 °C and in a relative humidity (RH) of 95% for a specific time. Changes in crystal structure were analyzed using differential calorimetry and wide-angle X-lay diffraction. The molecular weight (MW) was measured with gel permeation chromatography. The crystallinity of the amorphous PLA became the same as that of the initially annealed PLA within one hour at 70 °C and 95% RH. The MW of the amorphous PLA decreased faster even though the crystallinity was similar during the accelerated degradation. The low MW chains of the amorphous PLA tended to decrease faster, although changes in the MW distribution suggested random scission of the molecular chains for initially crystallized PLA. The concentrations of chain ends and impurities, which catalyze hydrolysis, in the amorphous region were considered to be different in the initial crystallization. The crystallinity alone does not determine the speed of hydrolysis.

Incomplete pseudo-Meigs' syndrome caused by endometrial ovarian cyst: A case report.

A 63-year-old female was admitted to our hospital with history of persistent dyspnea. Right pleural effusion and ovarian tumor were discovered, but here were no significant findings on thoracoscopy under local anesthesia. The pleural effusion was suspected to be secondary to Meigs' syndrome, and a diagnosis of endometriotic ovarian cyst was made. Since the pleural effusion resolved after surgery, the patient was diagnosed with incomplete pseudo-Meigs' syndrome. We consider this to be a valuable case, as there are no previously reported cases of pseudo-Meigs' syndrome derived from an endometriotic ovarian cyst, to the best of our knowledge.

Morphology, Thermal and Mechanical Properties of Co-Continuous Porous Structure of PLA/PVA Blends by Phase Separation.

Poly (lactic acid) (PLA) was blended with poly (vinyl alcohol) (PVA) in the composition of 70/30 (L7V3), 60/40 (L6V4), and 50/50 (L5V5) wt.%. L7V3 exhibits a sea-island morphology, while L6V4 and L5V5 show co-continuous phase morphologies. These polymers exhibited a solitary glass transition temperature, which obeyed the Fox equation. Thereafter, the blends were made porous by an etching process in hot water (35 °C) for 0-7 days, to remove PVA. The maximum etched PVA content of L7V3, L6V4, and L5V5 was 0.5%, 13.4%, and 36.1%, respectively; hence, L5V5 exhibited a co-continuous porous morphology with the porosity of 43.4%, the degree of swelling of 47.5%, and the pore size of 2 µm. The degree of crystallinity of PLA, exposed PLA, and L7V3 showed an insignificant change. L5V5, having the highest porosity, demonstrated the highest increase in the degree of crystallinity of approximately two times, because water induced the crystallization of PLA. The high porosity of L5V5 exhibited an excellent absorption property by increasing absorption energy more than two times, as obtained by micro indention. It had the maximum indentation depth more than 250 µm. Flexural and tensile properties considerably decreased with an increase in the porosity.