Synthesis, characterization and in vivo evaluation of honokiol bisphosphate prodrugs protects against rats' brain ischemia-reperfusion injury

Research progress of prodrugs for the treatment of cerebral ischemia

It is well-known that pharmacotherapy plays a pivotal role in the treatment and prevention of cerebral ischemia. Nevertheless, existing drugs, including numerous natural products, encounter various challenges when applied in cerebral ischemia treatment. These challenges comprise poor brain absorption due to low blood-brain barrier (BBB) permeability, limited water solubility, inadequate bioavailability, poor stability, and rapid metabolism. To address these issues, researchers have turned to prodrug strategies, aiming to mitigate or eliminate the adverse properties of parent drug molecules. In vivo metabolism or enzymatic reactions convert prodrugs into active parent drugs, thereby augmenting BBB permeability, improving bioavailability and stability, and reducing toxicity to normal tissues, ultimately aiming to enhance treatment efficacy and safety. This comprehensive review delves into multiple effective prodrug strategies, providing a detailed description of representative prodrugs developed over the past two decades. It underscores the potential of prodrug approaches to improve the therapeutic outcomes of currently available drugs for cerebral ischemia. The publication of this review serves to enrich current research progress on prodrug strategies for the treatment and prevention of cerebral ischemia. Furthermore, it seeks to offer valuable insights for pharmaceutical chemists in this field, offer guidance for the development of drugs for cerebral ischemia, and provide patients with safer and more effective drug treatment options.

Intelligent triggering of nanomicelles based on a ROS-activated anticancer prodrug and photodynamic therapy (PDT)-synergistic therapy for lung cancers

The intelligent triggering of drug release at targeted sites is essential for the safety and efficacy of cancer therapies. This study aimed to design and synthesize a novel prodrug (DHA-S-CA) using a reactive oxygen species (ROS)-responsive moiety, thioacetal, to bridge cinnamaldehyde (CA) and dihydroartemisinin (DHA). As ROS are highly expressed in tumor tissues, the design uses the ROS-responsive moiety as an effective target for the nanodrug delivery system. Furthermore, the near-infrared dye IR808 and the prodrug were adopted to prepare co-loaded Soluplus®/TPGS nanomicelles (IR808/DHA-S-CA NMs). The photosensitized agent IR808 exhibited both tumor accumulation and cancer imaging properties while generating ROS during laser irradiation. Intracellular ROS detection indicated that the prodrug DHA-S-CA could degrade via the high concentration of ROS in cancer cells induced by laser irradiation, and the released CA stimulated mitochondria to regenerate additional ROS to further improve the antitumor effect of DHA. Combined with photodynamic therapy (PDT), IR808/DHA-S-CA (+) NMs outperformed free DHA, DHA NMs, and IR808/DHA-S-CA (-) in a comparison of their pharmacokinetic profiles because it had a longer circulation time and a greater area under the curve (AUC). Compared with other DHA groups, the ROS-responsive IR808/DHA-S-CA (+) micelles had comparable cytotoxic activity. Furthermore, the ROS-responsive IR808/DHA-S-CA (+) micelles exhibited markedly higher anticancer efficiency on lung cancer cells than the other DHA groups. Overall, these results indicated that the therapeutic strategy of our novel small-molecule prodrug combined with PDT has great potential for the treatment of tumors.

The mechanism of curcumin post-treatment relieving lung injuries by regulating miR-21/TLR4/NF-κB signalling pathway

Objective

To investigate the mechanism by which curcumin prevents lung injury in a rat model of limb ischaemia-reperfusion injury.

Methods

Rats were randomized into four groups (n = 20): control group (sham group); ischaemia-reperfusion group (I/R group); curcumin group (I/R+Cur group); and inhibitor of agomir-21 group (I/R+Cur+antagomir-21 group). At 3 h after reperfusion, lung tissues were collected for histopathology and immunohistochemistry to determine the apoptosis index (AI). Lung injury score (LIS) and lung wet/dry (W/D) ratio were determined. Lung microRNA-21 (miR-21) mRNA levels were measured using reverse transcription–polymerase chain reaction. Toll-like receptor 4 (TLR4) and nuclear factor kappa-B p65 (NF-κB p65) protein levels were measured by Western blot analysis. Tumour necrosis factor (TNF)-α and interleukin (IL)-1β levels were determined by enzyme-linked immunosorbent assays.

Results

In the I/R group, the W/D, LIS, AI, miR-21 mRNA, TLR4, NF-κB p65, TNF-α and IL-1β were significantly increased and the PaO₂ was decreased compared with the sham group. Evidence of lung injury was observed in the I/R group and this was alleviated in the I/R+Cur group. An inhibitor of miR-21 (antagomir-21) reversed the protective effects of curcumin.

Conclusion

Curcumin post-treatment can alleviate the lung injuries induced by limb ischaemia-reperfusion via downregulating the levels of miR-21 mRNA.

Probing the drug delivery strategies in ischemic stroke therapy

Ischemic stroke, which is caused by a sudden clot in the blood vessels, may cause severe brain tissue damage and has become a leading cause of death globally. Currently, thrombolysis is the gold standard primary treatment of ischemic stroke in clinics. However, the short therapeutic window of opportunity limits thrombolysis utility. Secondary cerebral damage caused by stroke is also an urgent problem. In this review, we discuss the present methods of treating ischemic stroke in clinics and their limitations. Various new drug delivery strategies targeting ischemic stroke lesions have also been summarized, including pharmaceutical methods, diagnostic approaches and other routes. These strategies could change the pharmacokinetic behavior, improve targeted delivery or minimize side effects. A better understanding of the novel approaches utilized to facilitate drug delivery in ischemic stroke would improve outcomes.

Exosomal Formulation Escalates Cellular Uptake of Honokiol Leading to the Enhancement of Its Antitumor Efficacy

Honokiol is a phytochemical isolated from the Magnolia plant. It exhibits significant antitumor activity against a variety of cancer cell types via targeting of critical mediators of tumor progression, stromal remodeling, and chemoresistance. However, poor bioavailability and inefficient tumor uptake remain some of the hurdles in its translation as a therapeutically useful drug. Here, we developed a nanoformulation of honokiol using mesenchymal stem cell-derived exosomes, which are nonimmunogenic and express surface markers to support their tumor-targeted delivery. Maximum entrapment of honokiol occurred when it was mixed in a 1:4 weight ratio with exosomes and subjected to six cycles of sonication. Dynamic light scattering analysis demonstrated that the average size (∼175.3 nm), polydispersity (∼0.11), and integrity (∼12.9 mV) of exosomes remained in the desirable range post honokiol encapsulation. Exosome-encapsulated honokiol exhibited significantly higher therapeutic efficacy over the free honokiol in WST-1 growth and long-term clonogenicity assays. Flow cytometry-based cell cycle and live/dead cell assay, respectively, confirmed the enhanced effect of exosomal honokiol formulation on cell cycle arrest and apoptosis induction. More significant alterations in the expression of cell cycle- and survival-associated proteins were also observed in cancer cells treated with exosomal honokiol over free honokiol. Higher intracellular accumulation of honokiol was recorded in cancer cells treated with equivalent doses of honokiol as compared to the free honokiol. Together, our work is the first demonstration of exosomal encapsulation of honokiol and its improved antitumor efficacy resulting from improved cellular uptake.

Targeted delivery of honokiol by zein/hyaluronic acid core-shell nanoparticles to suppress breast cancer growth and metastasis

Based on the antisolvent and electrostatic deposition methods, we fabricated zein/hyaluronic acid core-shell nanoparticles loaded with honokiol (HA-Zein-HNK), which could target delivery and enhance the therapeutic effect of the HNK. The prepared nanoparticles were found to have a mean size of 210.4 nm and negative surface charge. The HA-Zein-HNK nanoparticles exhibited improved antiproliferative and pro-apoptotic activities against 4T1 cells. Of note, the wound healing and transwell assessments indicated that the migration and invasion of 4T1 cells were markedly weakened by HA-Zein-HNK. Mechanistic insights revealed that HA-Zein-HNK downregulated the expressions of Vimentin and upregulated the expressions of E-cadherin. More importantly, an in vivo tissue distribution study demonstrated the excellent tumor target ability of HA-Zein. And these results correspond with the superior therapeutic efficacy of HA-Zein-HNK in 4T1 tumor bearing mice. In conclusion, we believe that HA-Zein nanoparticles may be served as a promising HNK delivery carrier for metastatic breast cancer therapy.

Synthesis, Characterization, and In Vivo Evaluation of Desmethyl Anethole Trithione Phosphate Prodrug for Ameliorating Cerebral Ischemia-Reperfusion Injury in Rats

Anethol trithione (ATT) has a wide range of physiological activities, but its use is limited due to its poor water solubility. To improve the solubility of ATT, we synthesized and characterized a novel phosphate prodrug (ATXP) relying on the availability of the hydroxy group in 5-(4-hydroxyphenyl)-3H-1,2-dithiole3-thione (ATX), which was transformed from ATT rapidly and extensively in vivo. Our results showed that ATXP significantly improved drug solubility. ATXP was rapidly converted to ATX and reached a maximum plasma concentration with a T _max of approximately 5 min after intravenous (iv) administration. Furthermore, after the oral administration of ATXP, the C _max was 3326.30 ± 566.50 ng/mL, which was approximately 5-fold greater than that of the parent drug form, indicating that ATXP has greater absorption than that of ATT. Additionally, the oral phosphate prodrug ATXP increased the ATX in the area under the plasma concentration vs time curves (AUC_0-t = 3927.40 ± 321.50 and AUC_0-∞ = 4579.0 ± 756.30), making its use in practical applications more meaningful. Finally, compared to the vehicle, ATXP was confirmed to maintain the bioactivity of the parent drug for a significant reduction in infarct volume 24 h after reperfusion. Based on these findings, the phosphate prodrug ATXP is a potentially useful water-soluble prodrug with improved pharmacokinetic properties.

Novel approaches for the delivery of therapeutics in ischemic stroke

Here, we review novel approaches to deliver neuroprotective drugs to salvageable penumbral brain areas of stroke injury with the goals of offsetting ischemic brain injury and enhancing recovery.