ABSTRACT
Metal-exchanged zeolites have great potential to form unique active metal species and develop their catalysis by promoting small molecules such as light alkanes. Ga-exchanged zeolites have attracted attention as promising heterogeneous catalysts for dehydrogenative light-alkane transformations. The speciation of active Ga species in reduced and oxidized Ga-exchanged zeolites and their reaction mechanisms have been discussed in several studies based on experimental and theoretical investigations. In contrast, studies on In-exchanged zeolites have been far less explored, and thus active In-species have rarely been investigated. In this perspective, we summarized our investigations on In- and Ga-exchanged zeolites for light-alkane transformations. Our research group reported the formation of In-oxo clusters using the O2 treatment of In-CHA and their potential for the partial oxidation of CH4 (POM) at room temperature. We also observed the formation of In-hydrides in CHA zeolites during the preparation through reductive solid-state ion-exchange (RSSIE) and revealed their catalysis for non-oxidative C2H6 dehydrogenation (EDH). Their detailed structures and reaction mechanisms are discussed in combination with spectroscopic, kinetic, and theoretical studies. Furthermore, comparative studies on the formation of Ga-oxo clusters for POM at room temperature and the controlled formation of Ga-hydrides for selective EDH were conducted. The obtained results and insights are comprehensively discussed, including the relationship between the local structure of the active In/Ga species and reaction selectivity, as well as the influence of different zeolite frameworks on the formation of active species.
ABSTRACT
OBJECTIVE To mine and analyze severe cutaneous adverse reaction signals of 5 commonly used immune checkpoint inhibitors (ICIs), and to provide reference for clinically safe use of drugs. METHODS Based on the FDA adverse events reporting system (FAERS) database,adverse drug events (ADEs) reports about severe cutaneous adverse reactions related to ipilimumab, nivolumab, pembrolizumab, atezolizumab and durvalumab were collected from listing in the United States to the fourth quarter of 2022. The ADE signals were mined and analyzed with reporting odds ratio (ROR) and Bayesian confidence propagation neural network (BCPNN). RESULTS A total of 5 726 reports of severe cutaneous adverse reactions were collected, including 3 037 reports for nivolumab,1 465 reports for pembrolizumab, 130 reports for durvalumab, 429 reports for atezolizumab and 665 reports for ipilimumab. All 5 kinds of ICIs caused positive signals, the correlation degree of which was as follows: pembrolizumab>atezolizumab>nivolumab>ipilimumab>durvalumab. Stevens-Johnson syndrome(SJS) and toxic epidermal necrolysis (TEN) have been reported for all 5 ICIs, and the association was the strongest with pembrolizumab. CONCLUSIONS All 5 kinds of ICIs are associated with the risk of severe skin adverse reactions, and close attention should be paid to their clinical use, especially being cautious when using pembrolizumab. The combination of ICIs should be avoided as much as possible.
ABSTRACT
OBJECTIVE To provide references for the safe use of lorlatinib in clinical practice. METHODS The reporting odds ratio (ROR) method, Medicines and Healthcare Products Regulatory Agency comprehensive standard method (referred to as “MHRA method”) and the Bayesian confidence propagation neural network (BCPNN) method were used to detect adverse drug events (ADEs) signals of lorlatinib in the FDA Adverse Event Reporting System from the first quarter of 2019 to the fourth quarter of 2022. RESULTS & CONCLUSIONS Totally 114 overlapping ADEs signals of lorlatinib were detected by the three methods, among which there were 73 new suspicious ADEs signals which were not covered in the instruction of lorlatinib. When using loratinib in clinical practice, special attention should be paid to ADEs with a high number of cases and signals, such as various neurological diseases, psychiatric diseases, respiratory system, thoracic and mediastinal diseases; clinical manifestations included cerebral edema, cerebral infarction, pulmonary hypertension, mutism, decreased sexual desire, pleural effusion. The signals of mobile thrombophlebitis, radiation necrosis, mutism, vesicoureteral reflux not mentioned in the instructions were all strong in BCPNN detection with high specificity, to which we should pay attention in clinical application.
ABSTRACT
Qi-Yu-San-Long decoction(QYSLD)is a traditional Chinese medicine that has been clinically used in the treatment of non-small-cell lung cancer(NSCLC)for more than 20 years.However,to date,metabolic-related studies on QYSLD have not been performed.In this study,a post-targeted screening strategy based on ultra-performance liquid chromatography coupled with quadrupole time-of-flight full infor-mation tandem mass spectrometry(UPLC-QTOF-MSE)was developed to identify QYSLD-related xeno-biotics in rat urine.The chemical compound database of QYSLD constituents was established from previous research,and metabolites related to these compounds were predicted in combination with their possible metabolic pathways.The metabolites were identified by extracted ion chromatograms using predicted m/z values as well as retention time,excimer ions,and fragmentation behavior.Overall,85 QYSLD-related xenobiotics(20 prototype compounds and 65 metabolites)were characterized from rat urine.The main metabolic reactions and elimination features of QYSLD included oxidation,reduction,decarboxylation,hydrolysis,demethylation,glucuronidation,sulfation,methylation,deglycosylation,acetylation,and associated combination reactions.Of the identified molecules,14 prototype compounds and 58 metabolites were slowly eliminated,thus accumulating in vivo over an extended period,while five prototypes and two metabolites were present in vivo for a short duration.Furthermore,one pro-totype and five metabolites underwent the process of"appearing-disappearing-reappearing"in vivo.Overall,the metabolic profile and characteristics of QYSLD in rat urine were determined,which is useful in elucidating the active components of the decoction in vivo,thus providing the basis for studying its mechanism of action.
ABSTRACT
Coronavirus Disease 2019 (COVID-19) spreads globally as a sever pandemic, which is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Cell entry of SARS-CoV-2 mainly depends on binding of the viral spike (S) proteins to angiotensin converting enzyme 2 (ACE2) on host cells. Therefore, repurposing of known drugs to inhibit S protein-ACE2 interaction could be a quick way to develop effective therapy for COVID-19. Using a high-throughput screening system to investigate the interaction between spike receptor binding domain (S-RBD) and ACE2 extracellular domain, we screened 3581 FDA-approved drugs and natural small molecules and identified ceftazidime as a potent compound to inhibit S-RBD-ACE2 interaction by binding to S-RBD. In addition to significantly inhibit S-RBD binding to HPAEpiC cells, ceftazidime efficiently prevented SARS-CoV-2 pseudovirus to infect ACE2-expressing 293T cells. The inhibitory concentration (IC50) was 113.2 M, which is far below the blood concentration (over 300 M) of ceftazidime in patients when clinically treated with recommended dose. Notably, ceftazidime is a drug clinically used for the treatment of pneumonia with minimal side effects compared with other antiviral drugs. Thus, ceftazidime has both anti-bacterial and anti-SARS-CoV-2 effects, which should be the first-line antibiotics used for the clinical treatment of COVID-19.
