Cyanobacterial VOCs ß-ionone and ß-cyclocitral poisoning Lemna turionifera by triggering programmed cell death.

ß-Ionone and ß-cyclocitral are two typical components in cyanobacterial volatiles, which can poison aquatic plants and even cause death. To reveal the toxic mechanisms of the two compounds on aquatic plants through programmed cell death (PCD), the photosynthetic capacities, caspase-3-like activity, DNA fragmentation and ladders, as well as expression of the genes associated with PCD in Lemna turionifera were investigated in exposure to ß-ionone (0.2 mM) and ß-cyclocitral (0.4 mM) at lethal concentration. With prolonging the treatment time, L. turionifera fronds gradually died, and photosynthetic capacities gradually reduced and even disappeared at the 96th h. This demonstrated that the death process might be a PCD rather than a necrosis, due to the gradual loss of physiological activities. When L. turionifera underwent the death, caspase-3-like was activated after 3 h, and reached to the strongest activity at the 24th h. TUNEL-positive nuclei were detected after 12 h, and appeared in large numbers at the 48th h. The DNA was cleaved by Ca2+-dependent endonucleases and showed obviously ladders. In addition, the expression of 5 genes (TSPO, ERN1, CTSB, CYC, and ATR) positively related with PCD initiation was up-regulated, while the expression of 2 genes (RRM2 and TUBA) negatively related with PCD initiation was down-regulated. Therefore, ß-ionone and ß-cyclocitral can poison L. turionifera by adjusting related gene expression to trigger PCD.

A 100-V Withstanding Analog-Front-End for High-Resolution Intravascular Ultrasound Imaging.

Intravascular Ultrasound ultrasonic imaging (IVUS) can microscopically image blood vessels and reveal tissue layers from within the blood vessel lumen. It has high tissue penetration ability for lesion classification and can image through blood. Compared to optical techniques, however, IVUS has lower resolution arising from low acoustic bandwidths which cannot resolve sharp edges. The presented 100-V withstanding Analog-Front-End (AFE) was developed to enable a high resolution, low cost IVUS system using a high-bandwidth focused polymer transducer with 40-MHz center frequency. The fabricated AFE interfaced with the transducer with minimal insertion loss, could withstand and duplex 100-V high voltage pulses and echo signal, and had a total signal chain gain of 9.8 dB. The AFE achieved a signal-to-noise ratio (SNR) of 20.1 dB including the insertion loss of the high-impedance transducer. AFE SNR was limited by input impedance required for high-voltage pulse clamping circuitry, but was sufficient for IVUS echo reception.Clinical Relevance- This work has the potential to enable much higher resolution, and potentially cheaper, IVUS imaging in blood vessels by integrating low-cost acoustic transducers with interface amplifiers directly on the catheter.