N-acetylcysteine mitigates oxidative damage to the ovary in D-galactose-induced ovarian failure in rabbits.

BACKGROUND: Oxidative damage to the ovaries is the primary cause of impaired reproductive functions in female animals. This study aimed to investigate the protective role of N-Acetyl-L-cysteine (NAC) in reducing oxidative damage in the ovaries of female rabbits. METHODS AND RESULTS: Female rabbit ovaries were treated in vitro with varying concentrations of D-galactose (D-gal): 0, 5, 10, and 15 mg/mL, and it was found that 10 mg/mL D-gal significantly disrupted follicular structures, causing disarray in granulosa cell arrangements and significantly reducing T-SOD and GSH levels (p < 0.01). Consequently, we selected 10 mg/mL D-gal to establish an ovarian failure model. These models were treated with multiple doses of NAC (0, 0.1, 0.3, 0.5 mg/mL). The results revealed that the disruption in granulosa cell arrangement caused by 10 mg/mL D-gal was effectively alleviated by 0.1 mg/mL NAC compared to the D-gal treatment group. Furthermore, 10 mg/mL D-gal significantly (p < 0.01) reduced GSH, T-SOD, and catalase (CAT) levels in the ovaries. However, 0.1 mg/mL NAC effectively (p < 0.01) suppressed these adverse effects. Moreover, the current results showed that 10 mg/mL D-gal alone significantly (p < 0.01) downregulated the expression of Nrf2, GPX, PRDX4, GSR, SOD1, and TAF4B, whereas 0.1 mg/mL NAC counteracted these suppressive effects (p < 0.01). CONCLUSIONS: It could be concluded that NAC may delay ovarian failure by reducing D-gal-induced ovarian oxidative damage in female rabbit, suggested NAC could be a promising therapeutic agent for protecting against ovarian failure and potentially delaying ovarian failure in female rabbits.

A Photolysis-Assist Molecular Communication for Tumor Biosensing.

Molecular communication (MC) is a promising bioinspired paradigm for exchanging molecule information among nanomachines. In this paper, we propose a synchronization-assist photolysis MC system that aims to transmit the biosensing signal of the tumor microenvironment, facilitated by mitigating redundant molecules for improved bit error rate (BER) performance. Benefits from biocompatible MC, biosensors could transmit biosensing signals of the tumor in vivo instead of converting them to electrical signals. Due to diffusion motion's slow and stochastic nature, intersymbol interference (ISI), resulting from previous symbols' residual information molecules, inevitably occurs in diffusion-based MC. ISI is one of the challenges in diffusion-based MC, which significantly impacts signal detection. Inspired by on-off keying (OOK) modulation, the proposed modulation implements a switch of molecules and light alternatively. The light emitted is triggered by a synchronization signal, and the photolysis reactions could reduce the redundant molecules. An expression for the relevant channel impulse response (CIR) is derived from a hybrid channel model of diffusion and photolysis reaction. In this paper, we implement the maximum posterior estimation scheme to find the optimal decision threshold and analysis the BER performance in terms of different time intervals of the system. Numerical simulations demonstrate that the proposed method can improve the channel capacity and BER performance. We believe that our work may pave the way for MC application in biosensing.

Bioinspired Ferroelectric Polymer Arrays as Photodetectors with Signal Transmissible to Neuron Cells.

A bioinspired photodetector with signal transmissible to neuron cells is fabricated. Photoisomerization of the dye molecules embedded in the ferroelectric polymer membrane achieves electric polarization change under visible light. The photodetector realizes high sensitivity, color recognition, transient response, and 3D visual detection with resolution of 25 000 PPI, and, impressively, directly transduces the signal to neuron cells.