Understanding Health Care Provider Burnout When Caring for Patients With Refractory Epilepsy in the United States.

Background and Objectives: Among health care providers (HCPs), neurologists have one of the highest rates of burnout in the United States, compromising the quality and accessibility of patient care. Patients with refractory epilepsy are especially challenging to treat. This study aims to understand the burnout level in neurologists treating patients with refractory epilepsy and identify key contributing factors. Methods: US board-certified pediatric/adult neurologists who devote ≥50% of their time to clinical practice and treat ≥10 unique patients with refractory epilepsy annually were invited to take a noninterventional quantitative survey, designed to capture key elements of the HCP's background, burnout level, current practice, burden domains, and satisfaction with current antiseizure medications (ASMs). Burnout in 3 domains (emotional exhaustion, depersonalization, and personal accomplishment) was assessed by the validated Maslach Burnout Inventory-Human Services Survey. Results: From March 11, 2022, to April 10, 2022, a total of 138 neurology-specialist HCPs participated in the survey, divided between adult epileptologists (n = 44), adult neurologists (n = 41), pediatric epileptologists (n = 36), and pediatric neurologists (n = 17). Of participating HCPs, 61% experienced at least some burnout (≥1 of 3 burnout domains categorized as high), and 4% experienced high burnout (3 of 3 burnout domains categorized as high). High burnout levels were driven by high pediatric and inpatient caseloads and unexpected pediatric patient reluctance to transition to adult care. HCPs with high burnout had a higher yearly caseload of patients with refractory epilepsy. Most HCPs (approximately 90%) indicated that patients with refractory epilepsy were more difficult to manage than those with nonrefractory epilepsy. The proportion of HCPs satisfied or extremely satisfied with ASMs was lower for patients with refractory epilepsy (20%) than that for patients with nonrefractory epilepsy (73%). Dissatisfaction was mostly due to workload and latency of the insurance approval process, out-of-pocket costs, and poor efficacy, safety, and tolerability. For 32% of HCPs, stopping practicing or moving to another practice within 5 years was probable or very probable. Discussion: Some burnout is common among HCPs who treat patients with refractory epilepsy. However, management of refractory epilepsy is challenging, and satisfaction with available ASMs is low. Thus, addressing these contributing factors may help to alleviate HCP burnout.

A dual-action antibiotic that kills Clostridioides difficile vegetative cells and inhibits spore germination.

Clostridioides difficile infection (CDI) is the most lethal of the five CDC urgent public health treats, resulting in 12,800 annual deaths in the United States alone [Antibiotic Resistance Threats in the United States, 2019 (2019), www.cdc.gov/DrugResistance/Biggest-Threats.html]. The high recurrence rate and the inability of antibiotics to treat such infections mandate discovery of new therapeutics. A major challenge with CDI is the production of spores, leading to multiple recurrences of infection in 25% of patients [C. P. Kelly, J. T. LaMont, N. Engl. J. Med. 359, 1932-1940 (2008)], with potentially lethal consequence. Herein, we describe the discovery of an oxadiazole as a bactericidal anti-C. difficile agent that inhibits both cell-wall peptidoglycan biosynthesis and spore germination. We document that the oxadiazole binds to the lytic transglycosylase SleC and the pseudoprotease CspC for prevention of spore germination. SleC degrades the cortex peptidoglycan, a critical step in the initiation of spore germination. CspC senses germinants and cogerminants. Binding to SleC is with higher affinity than that to CspC. Prevention of spore germination breaks the nefarious cycles of CDI recurrence in the face of the antibiotic challenge, which is a primary cause of therapeutic failure. The oxadiazole exhibits efficacy in a mouse model of recurrent CDI and holds promise in clinical treatment of CDI.

Structure-Activity Relationship for the Picolinamide Antibacterials that Selectively Target Clostridioides difficile.

Clostridioides difficile is a leading health threat. This pathogen initiates intestinal infections during gut microbiota dysbiosis caused by oral administration of antibiotics. C. difficile is difficult to eradicate due to its ability to form spores, which are not susceptible to antibiotics. To address the urgent need for treating recurrent C. difficile infection, antibiotics that selectively target C. difficile over common gut microbiota are needed. We herein describe the class of picolinamide antibacterials which show potent and selective activity against C. difficile. The structure-activity relationship of 108 analogues of isonicotinamide 4, a compound that is equally active against methicillin-resistant Staphylococcus aureus and C. difficile, was investigated. Introduction of the picolinamide core as exemplified by analogue 87 resulted in exquisite potency and selectivity against C. difficile. The ability of the picolinamide class to selectively target C. difficile and to prevent gut dysbiosis holds promise for the treatment of recurrent C. difficile infection.

Discovery of a Potent Picolinamide Antibacterial Active against Clostridioides difficile.

A major challenge for chemotherapy of bacterial infections is perturbation of the intestinal microbiota. Clostridioides difficile is a Gram-positive bacterium of the gut that can thrive under this circumstance. Its production of dormant and antibiotic-impervious spores results in chronic disruption of normal gut flora and debilitating diarrhea and intestinal infection. C. difficile is responsible for 12,800 deaths per year in the United States. Here, we report the discovery of 2-(4-(3-(trifluoromethoxy)phenoxy)picolinamido)benzo[d]oxazole-5-carboxylate as an antibacterial with potent and selective activity against C. difficile. Its MIC50 and MIC90 (the concentration required to inhibit the growth of 50% and 90% of all the tested strains, respectively) values, documented across 101 strains of C. difficile, are 0.12 and 0.25 µg/mL, respectively. The compound targets cell wall biosynthesis, as assessed by macromolecular biosynthesis assays and by scanning electron microscopy. Animals infected with a lethal dose of C. difficile and treated with compound 1 had a similar survival compared to treatment with vancomycin, which is the frontline antibiotic used for C. difficile infection.

Cinnamonitrile Adjuvants Restore Susceptibility to ß-Lactams against Methicillin-Resistant Staphylococcus aureus.

ß-Lactams are used routinely to treat Staphylococcus aureus infections. However, the emergence of methicillin-resistant S. aureus (MRSA) renders them clinically precarious. We describe a class of cinnamonitrile adjuvants that restore the activity of oxacillin (a penicillin member of the ß-lactams) against MRSA. The lead adjuvants were tested against six important strains of MRSA, one vancomycin-intermediate S. aureus (VISA) strain, and one linezolid-resistant S. aureus strain. Five compounds out of 84 total compounds showed broad potentiation. At 8 µM (E)-3-(5-(3,4-dichlorobenzyl)-2-(trifluoromethoxy)phenyl)-2-(methylsulfonyl)acrylonitrile (26) potentiated oxacillin with a >4000-fold reduction of its MIC (from 256 to 0.06 mg·L-1). This class of adjuvants holds promise for reversal of the resistance phenotype of MRSA.

Mechanism of the Escherichia coli MltE lytic transglycosylase, the cell-wall-penetrating enzyme for Type VI secretion system assembly.

Lytic transglycosylases (LTs) catalyze the non-hydrolytic cleavage of the bacterial cell wall by an intramolecular transacetalization reaction. This reaction is critically and broadly important in modifications of the bacterial cell wall in the course of its biosynthesis, recycling, manifestation of virulence, insertion of structural entities such as the flagellum and the pili, among others. The first QM/MM analysis of the mechanism of reaction of an LT, that for the Escherichia coli MltE, is undertaken. The study reveals a conformational itinerary consistent with an oxocarbenium-like transition state, characterized by a pivotal role for the active-site glutamic acid in proton transfer. Notably, an oxazolinium intermediate, as a potential intermediate, is absent. Rather, substrate-assisted catalysis is observed through a favorable dipole provided by the N-acetyl carbonyl group of MurNAc saccharide. This interaction stabilizes the incipient positive charge development in the transition state. This mechanism coincides with near-synchronous acetal cleavage and acetal formation.

Structure-activity relationship of the cinnamamide family of antibiotic potentiators for methicillin-resistant Staphylococcus aureus (MRSA).

Methicillin-resistant Staphylococcus aureus (MRSA) is a global public health threat. MRSA has evolved a complex set of biochemical processes that mobilize the organism for inducible resistance on challenge by ß-lactam antibiotics. Interfering pharmacologically with this machinery has the potential to reverse the ß-lactam-resistance phenotype, whereby susceptibility to obsolete antibiotics would be restored. We describe herein our discovery of one class of such agents, the cinnamamide family of antibiotic potentiators. A hit compound of the class (compound 1) showed modest potentiation of the activity of oxacillin, a penicillin antibiotic, against an MRSA strain. A total of 50 analogues of compound 1 were prepared and screened. Seven of these compounds showed more dramatic potentiation of the antibacterial activity, which lowered the minimal-inhibitory concentrations (MICs) for the antibiotic by as much as 64- to 128-fold.