Naringenin alleviates bone cancer pain via NF-κB/uPA/PAR2 pathway in mice.

PURPOSE: This investigation aims to explore the protective role of Naringenin (Nar) in bone cancer pain (BCP) via TNF-α-mediated NF-κB/uPA/PAR2 pathway. METHODS: BCP model was manipulated by the injection of LL2 cells into femur of mice. The levels of TNF-α and uPA in bone tissue and serum were studied by ELISA. The expressions of PAR2, PKC-γ, PKA and TRPV1 were determined by qPCR and western blot. Levels of p-IKKß, IKKß, p-p65, p65 were determined by western blot. Levels of p-p65 and uPA in bone tissue were studied by immunohistochemistry. Behavior tests in this investigation included paw withdrawal latency (PWL) and the paw withdrawal threshold (PWT). Radiological analysis and micro-CT were used to study bone structure. The lesions of bone tissue were determined by HE staining. The Dorsal root ganglia (DRG) isolated from mice were used to determine the level of PAR2 pathway. RESULTS: Naringenin improved the BCP-induced bone damage based on the increases of BV/TV, Conn. D, BMD and BMC and the decrease of bone destruction score. Naringenin repressed the reductions of PWT and PWL in BCP mice. Naringenin decreased the levels of PAR2, PKC-γ, PKA and TRPV1 of DRG and reduced the levels of p-IKKß, p-p65, and uPA in serum and bone tissue in BCP. Importantly, naringenin suppressed the enhancement of TNF-α in serum and bone tissue in BCP mice. CONCLUSION: Naringenin alleviated pain sensitization and bone damage of mice with BCP via TNF-α-mediated NF-κB/uPA/PAR2 pathway. We demonstrated a novel pathway for anti-BCP treatment with naringenin.

Knockdown of PAR2 alleviates cancer-induced bone pain by inhibiting the activation of astrocytes and the ERK pathway.

OBJECTIVE: Cancer-induced bone pain (CIBP) is a kind of pain with complex pathophysiology. Proteinase-activated receptor 2 (PAR-2) is involved in CIBP. This study explored the effects of PAR-2 on CIBP rats. METHODS: CIBP rat model was established by injecting Walker 256 rat breast cancer cells into the left tibia of female Sprague-Dawley rats and verified by tibial morphology observation, HE staining, and mechanical hyperalgesia assay. CIBP rats were injected with PAR-2 inhibitor, ERK activator, and CREB inhibitor through the spinal cord sheath on the 13th day after operation. CIBP behaviors were measured by mechanical hyperalgesia assay. On the 14th day after operation, L4-5 spinal cord tissues were obtained. PAR-2 expression, co-expression of PAR-2 and astrocyte marker GFAP, GFAP mRNA and protein levels and the ERK pathway-related protein levels were detected by Western blot, immunofluorescence double staining, RT-qPCR, and Western blot. RESULTS: CIBP rats had obvious mechanical hyperalgesia and thermal hyperalgesia from the 7th day after modeling; mechanical hyperalgesia threshold and thermal threshold were decreased; PAR-2 was increased in spinal cord tissues and was co-expressed with GFAP. PAR-2 silencing alleviated rat CIBP by inhibiting astrocyte activation. p-ERK/t-ERK and p-CREB/t-CREB levels in CIBP spinal cord were elevated, the ERK/CREB pathway was activated, while the ERK/CREB pathway was inhibited by PAR-2 silencing. The alleviating effect of PAR-2 inhibitor on hyperalgesia behaviors in CIBP rats were weakened by ERK activator, while were partially restored by CREB inhibitor. CONCLUSIONS: PAR-2 knockdown inhibited the ERK/CREB pathway activation and astrocyte activation, thus alleviating CIBP in rats.

Atomically dispersed Fe-N-C catalyst displaying ultra-high stability and recyclability for efficient electroreduction of CO2 to CO.

To avoid the agglomeration of iron NPs and improve the dispersion of Fe SAs, we employed a mixed-ligand strategy to regulate the iron content in PCN-224(ZnxFey) and PCN-222(ZnxFey). Thanks to the sublimation of Zn and the Kirkendall effect, uniform dispersions of Fe SAs with 1.04-1.06 wt% were obtained in the pyrolysis products Zn0.5Fe0.5-N-C-224 and Zn0.5Fe0.5-N-C-222 with excellent CO2 → CO activity, super-stability, and recyclability.

Effects of acupoint massage combined with relaxation therapy on patients with postoperative fatigue syndrome after lumbar surgery.

BACKGROUND: : Lumbar disc herniation (LDH) is a common disease in orthopedics. Surgery is shown to provide significant faster relief of pain compared to conservative therapy. However, due to the influence of surgical trauma, anesthesia and other perioperative stress factors, patients may have complications. Among them, postoperative fatigue syndrome (POFS) is a common complication. Traditional Chinese medicine or integrated traditional Chinese and Western medicine have been proved to be effective in improving postoperative fatigue. METHODS: : This study is a randomized controlled trial. One hundred eighty Chinese patients with POFS of LDH will be randomly divided into control group, experimental group 1, experimental group 2 and experimental group 3 according to the ratio of 1:1:1:1. The patients in the control group will be treated with conventional treatment after operation, the patients in the experimental group 1 will be treated with acupoint massage, the patients in the experimental group 2 will be treated with relaxation therapy, and the patients in the experimental group 3 will be treated with acupoint massage combined with relaxation therapy. The whole treatment will last for 5 days. The main outcome measures will be fatigue visual analogue scale and identity-consequence fatigue scale, and the secondary outcome measures will be hospital anxiety and depression scale. DISCUSSION: : This study is to observe the effects of acupoint massage comblined with relaxation therapy on reducing postoperative fatigue of lumbar disc herniation surgical patients. TRIAL REGISTRATION: : Chinese Clinical Trial Registry (http://www.chictr.org.cn/edit.aspx?pid=123978&htm=4), No. ChiCTR2100044788. Registered on March 27, 2021.

Revealing the structure-activity relationship of two Cu-porphyrin-based metal-organic frameworks for the electrochemical CO2-to-HCOOH transformation.

The eCO2RR activity is correlated to the internal structural character of the catalyst. We employed two types of structural models of porphyrin-based MOFs of PCN-222(Cu) and PCN-224(Cu) into heterogeneous catalysis to illustrate the effect of structural factors on the eCO2RR performance. The composite catalyst PCN-222(Cu)/C displays better activity and selectivity (η = 450 mV, FEHCOOH = 44.3%, j = 3.2 mA cm-2) than PCN-224(Cu)/C (η = 450 mV, FEHCOOH = 34.1%, j = 2.4 mA cm-2) for the CO2 reduction to HCOOH in the range of -0.7--0.9 V (vs. RHE) due to its higher BET surface area, CO2 uptake, and a larger pore diameter. It is interesting that PCN-224(Cu)/C displays better performance in the range of -0.4--0.6 V (vs. RHE) due to its greater heat of adsorption, Qst and a higher affinity for CO2 molecule, which could promote the capture of CO2 onto the exposed active sites. As a result, PCN-224(Cu)/C exhibits better stability for the long-term electrolysis.

Ru decorated with NiCoP: an efficient and durable hydrogen evolution reaction electrocatalyst in both acidic and alkaline conditions.

The construction of a high efficiency and stable catalyst for use in electrochemical hydrogen generation has great significance for renewable energy technologies. Herein, we show for the first time that Ru decorated with NiCoP is an excellent hydrogen evolving catalyst in both acidic and alkaline conditions, close in performance to that of Pt/C.