Rapid Transition to a Virtual Multiple Mini-Interview Admissions Process: A New Medical School's Experience During the COVID-19 Pandemic.

PROBLEM: The University of Houston College of Medicine (UH COM) began its first admissions cycle after receiving preliminary accreditation in February 2020. With the advent of remote learning in response to the COVID-19 pandemic, the school moved its admissions process, including multiple mini-interview (MMI), from an in-person to online format in mid-March 2020. APPROACH: The UH COM selected Zoom as the video conferencing platform for its virtual admissions process, including MMI. On each interview day (3-4 hours), 14-16 applicants joined administrators, faculty, and staff in a virtual meeting room. Applicants were divided into 2 groups: one viewed short presentations about the school, curriculum, and departments, while the other participated in 7 MMI stations (one-on-one interactions with interviewers) via virtual breakout rooms; the groups then switched. The MMI stations were the same as those used in-person in early March. Applicants were able to ask questions at multiple points during the day. Technical support was provided for participants with connectivity issues or unfamiliar with Zoom. OUTCOMES: Of the 180 applicants interviewed in March-April 2020, 134 (74%) participated in the virtual process and 46 (26%) in the on-site process. Twenty-five (83%) of the 30 members of the inaugural class of 2024 interviewed virtually. Advantages of the virtual format included ease of access for faculty and more flexibility and less expense for applicants. Challenges included the need for applicants to decide whether to accept an offer of admission from a new school without visiting and missed opportunities for faculty to have relatively unstructured interactions with applicants. NEXT STEPS: This virtual admissions process was a feasible alternative for the inaugural class but is not sustainable. UH COM plans to leverage lessons learned to refine the virtual format for use in future admissions cycles, even when in-person interviews are possible.

Antecedent ethanol ingestion prevents postischemic microvascular dysfunction.

Prolonged ischemia followed by reperfusion (I/R) results in impaired endothelial cell function in all segments of the microvasculature. Moreover, microcirculatory dysfunction plays a major role in the genesis of the reperfusion component of total tissue injury in I/R. Thus, preservation of endothelial function is an important therapeutic goal for ameliorating injury in tissues subjected to I/R. An accumulating body of evidence indicates that low to moderate ethanol consumption produces an adaptive transformation to a protected phenotype in both microvascular endothelium and parenchymal cells such that they are rendered resistant to the pathologic effects of I/R. The purpose of this review is to summarize our current understanding of the signaling pathways underlying the development of the preconditioned state induced by antecedent ethanol in arteriolar, capillary, and venular endothelium. In addition, we will highlight understudied areas with regard to microvascular protection afforded by antecedent ethanol in the hopes that this will stimulate investigation of its underlying mechanisms. Understanding these signaling pathways may provide a mechanistic rationale for the development of novel treatment interventions that target both the microcirculatory and parenchymal sequelae to I/R, thereby maximizing the therapeutic potential of the protected phenotypes produced by pharmacologic preconditioning.

Late preconditioning by ethanol is initiated via an oxidant-dependent signaling pathway.

Ingestion of alcoholic beverages at low to moderate levels 24 h prior to ischemia and reperfusion (I/R) prevents postischemic leukocyte/endothelial cell adhesive interactions, a phenomenon referred to as late ethanol preconditioning (EtOH-PC). The aim of this study was to determine whether oxidants act as initiators of late EtOH-PC. Ethanol was instilled into the stomachs of C57BL/6 mice as a bolus by gavage at a dose that produced a peak plasma concentration of 45 mg/dl 30 min after administration and returned to control levels 60 min after ingestion. Twenty four hours later, the superior mesenteric artery was occluded for 45 min followed by 70 min of reperfusion. The numbers of rolling and firmly adherent leukocytes were quantified in postcapillary venules of the small intestine in sham animals (no EtOH-PC, no I/R), in mice subjected to I/R alone or EtOH-PC + I/R, and in animals treated with Mn-TBAP (a cell-permeant superoxide dismutase mimetic), oxypurinol (a XO inhibitor), the NAD(P)H oxidase inhibitors PR-39 or apocynin, or oxypurinol plus PR39 during the period of EtOH-PC on Day 1 followed by I/R on Day 2. In separate groups of mice, oxypurinol or apocynin were also administered 1 h after ethanol ingestion on Day 1, with induction of I/R 24 h later. I/R induced marked increases in leukocyte rolling and adherence, effects that were completely prevented by EtOH-PC. Coincident treatment with Mn-TBAP, oxypurinol, PR-39, apocynin, or oxypurinol plus PR-39 with ethanol attenuated these anti-inflammatory actions of EtOH-PC. However, administration of oxypurinol or apocynin 1 h after ethanol ingestion failed to prevent these protective effects of EtOH-PC. Our results indicate that reactive oxygen species formed during the period of ethanol exposure on Day 1 trigger the development of an anti-inflammatory phenotype that renders the small bowel resistant to the proadhesive effects of I/R 24 h later.