Equine-Assisted Learning - An Experiential, Facilitated Learning Model for Development of Professional Skills and Resiliency in Veterinary Students.

Stress has been identified as a major obstacle for students in DVM training programs and can be associated with a high incidence of anxiety and depression among students. Interventions for stress reduction and improved self-confidence have been introduced at many veterinary schools with the intention of increasing resiliency among students and improving skills for wellness to be used throughout a veterinary career. Equine-assisted learning (EAL) is a facilitated, reflective discussion method based on interpretation of equine behavior in a group experiential setting that has been used to improve confidence, self-assurance, verbal and non-verbal communication, focus, mindfulness, and coping strategies in populations of students, medical students, corporate groups, and career professionals. We worked with the Cummings School equine teaching herd to develop an EAL course offered as a weekly class to veterinary students in Spring and Fall semesters since 2018. Our course was modeled after one offered to medical students at the University of Arizona and Stanford University, using progressively more complex equine handling exercises over the course of the semester (Kane, 2007). Our goal was improved communication, focus, and self-awareness among students to help reduce stress and improve resiliency. Outcome surveys showed that the students found a safe space to share anxieties, concerns, or challenges and learn professionalism skills. Incidentally, they also reported improvement in their equine handling skills. We advocate the use of EAL principles and the use of veterinary teaching horses to reduce stress and improve resiliency and equine handling skills among veterinary students.

Assessment and Revision of the Veterinary Internship and Residency Matching Program Standardized Letter of Reference.

The Veterinary Internship and Residency Matching Program (VIRMP) recently revised its electronic standardized letter of reference (SLOR) to improve the quality and usefulness of the data obtained from it and to enhance the relevance of non-cognitive and cognitive candidate attributes assessed. We used a stepwise process including a broad survey of SLOR readers and writers, analysis of past SLORs, and a multi-wave iterative revision that included key stakeholders, such as residency and internship program directors from academia and private practice. Data from the SLOR survey and analysis of past SLOR responses identified opportunities to improve applicant differentiation, mitigate positive bias, and encourage response consistency. The survey and other analytics identified and confirmed performance domains of high relevance. The revised SLOR assesses four performance domains: knowledge base and clinical skills, stress and time management, interpersonal skills, and personal characteristics. Ratings within the revised SLOR are predominantly criterion-referenced to enhance discernment of candidate attributes contained within each domain. Questions assessing areas of strength and targeted mentoring were replaced with free-text boxes, which allow writers to comment on positive and neutral/negative ratings of attributes within domains. Minor revisions were made to certain questions to enhance readability, streamline responses, or address targeted concerns identified in the SLOR survey or stakeholder review. The revised SLOR was deployed in the 2020 VIRMP; data from a survey of writers (n = 647) and readers (n = 378) indicate that the redesign objectives were achieved.

Optimization of Electronic Medical Records for Data Mining Using a Common Data Model.

The increasing use of electronic health records (EHRs) in veterinary medicine creates an opportunity to utilize the high volume of electronic patient data for mining and data-driven analytics with the goal of improving patient care and outcomes. A central focus of the Clinical and Translational Science Award One Health Alliance (COHA) is to integrate efforts across multiple disciplines to better understand shared diseases in animals and people. The ability to combine veterinary and human medical data provides a unique resource to study the interactions and relationships between animals, humans, and the environment. However, to effectively answer these questions, veterinary EHR data must first be prepared in the same way it is now commonly being done in human medicine to enable data mining and development of analytics to facilitate knowledge formation and solutions that advance our understanding of disease processes, with the ultimate goal of improving outcomes for veterinary patients and their owners. As a first step, COHA member institutions implemented a Common Data Model to standardize EHR data. Herein we present the approach executed within the COHA framework to prepare and optimize veterinary EHRs for data mining and knowledge formation based on the adoption of the Observational Health Data Sciences and Informatics' Observational Medical Outcomes Partnership Common Data Model.

TRANSLATOR Database-A Vision for a Multi-Institutional Research Network.

The formation of the CTSI One Health Alliance (COHA) network has generated the infrastructure necessary to support "Big Data" collaborative comparative and translational research in veterinary medicine. We describe the first step in the design, implementation, and dissemination of a collaborative information technology infrastructure that will serve the public and clinicians (COHA public/member based web site at https://ctsaonehealthalliance.org/) and its research focused COHA Research Workbench application. The core research infrastructure, TRANSLATOR (TRanslational ANimal Shared ColLAboraTive Observational Research), represents the foundation of a federated research-capable network to enable pooling large datasets from both electronic health records and publications. The public facing COHA website is a mechanism for both the dissemination of knowledge to the public and to foster collaborations amongst veterinary clinician scientists and the greater medical research community.

Vital organ tissue oxygenation after serial normovolemic exchange transfusion with HBOC-201 in anesthetized swine.

This study determined the effects of serial, normovolemic, stepwise exchange transfusions with either 6% human serum albumin (HSA) or the hemoglobin-based oxygen carrier, HBOC-201, on tissue oxygenation of the heart, brain, and kidney in intact anaesthetized pigs. Exchange transfusions to 10%, 30%, and 50% of the pigs' total blood volume were completed at a withdrawal rate of 1.0 mL·kg(-1)·min(-1) followed by an infusion rate of 0.5 mL·kg(-1)·min(-1) of HBOC-201 or iso-oncotically matched 6% HSA. Measurements included invasive systemic hemodynamic (blood pressures, left ventricular end-diastolic pressure), hematolic (hemoglobin, hematocrit, methemoglobin), acid-base (pH, PCO2), and biochemistry (serum lactate) measurements. Brain and kidney tissue oxygenation (tPO2) was determined by electron paramagnetic resonance and heart tPO2 by O2 sensitive fiberoptic probe. The main results demonstrated that tPO2 after HBOC-201 remained stable despite significant decreases in hematocrit and changing hemodynamics. In vivo tPO2 measurements (heart tPO2 average ≥22 mmHg, brain tPO2 average ≥8 mmHg, and kidney tPO2 average ≥10 mmHg) were maintained in all groups at all times. Blood pressures were 20 to 30 mmHg higher after HBOC-201 compared with HSA controls. Heart rate and left ventricular end-diastolic pressure were not different among treatment groups. In conclusion, the administration of HBOC-201 maintained tPO2 in three vital organs after profound hemodilution.

Regional blood flow after serial normovolemic exchange transfusion with HBOC-201 (Hemopure) in anesthetized swine.

BACKGROUND: This study determined individual organ blood flows and global hemodynamic, oxygen delivery and consumption parameters after normovolemic exchange transfusions with the hemoglobin based oxygen carrier (HBOC)-201 in a lightly anesthetized swine model. METHODS: The exchange transfusions were performed as a stepped reduction in blood volume to attain volume exchanges of 10%, 30%, and 50% with a 1:1 replacement with HBOC-201 (n = 8) or oncotically matched 5.9% human serum albumin (HSA, n = 8). Four additional animals served as time controls. RESULTS: There was no change in the regional blood flows in 8 of 9 organs (brain, heart, kidney, liver, pancreas, gall bladder, small intestines, large intestines, and skeletal muscle) after HBOC-201 compared with controls; only skeletal muscle blood flow decreased. In contrast, with HSA, blood flow increased 150% to 200% of baseline in all organs except muscle where blood flow was unchanged. HBOC-201 effectively restored oxygen delivery after these exchanges. The mean arterial pressure increases in the HBOC-201 group were within 15% to 20% of baseline during the initial 10% exchange and similar to controls during subsequent exchanges. Although peak pulmonary arterial pressure increases in the HBOC-201 group were 10 mm Hg to 15 mm Hg above baseline, cardiac index was unchanged. There were no differences in global oxygen consumption, consistent with unchanged regional blood flow and suggests intact physiologic coupling of oxygen delivery and consumption that was unimpaired by local vasoconstriction. This is in contrast to significant changes of increased cardiac index, decreased arterial pressure, decreased oxygen content, and increased oxygen extraction ratio to maintain normal oxygen consumption in the HSA group. CONCLUSION: Although the use of HBOC-201 caused alterations in systemic (minimal) and pulmonary (modest) pressures, these changes had no consequence on regional organ blood flow.

The effects of decreasing low-molecular weight hemoglobin components of hemoglobin-based oxygen carriers in swine with hemorrhagic shock.

BACKGROUND: Some hemoglobin-based oxygen carriers (HBOCs) improve outcome in animal models of hemorrhagic shock (HS) in comparison with standard asanguinous resuscitation fluids. Nevertheless, concern about intrinsic vasoactivity, linked in part to low-molecular weight (MW) hemoglobin (Hb), has slowed HBOC development. We assessed the impact of decreasing the low-MW Hb component of bovine HBOC on vasoactivity in severe HS. METHODS: Anesthetized invasively monitored swine were hemorrhaged 55% blood volume and resuscitated with bovine HBOC containing 31% (31 TD [HBOC-301]), 2% (2 TD [HBOC-201]), or 0.4% (0.4 TD) low-MW Hb. Pigs received four 10 mL/kg infusions over 60 minutes, hospital arrival was simulated at 75 minutes, organ blood flow (BF) was evaluated by microsphere injection, and monitoring was continued for 4 hours followed by complete necrotic evaluation. RESULTS: There were few differences between 2 TD and 0.4 TD. Thirty-one TD pigs had higher systemic and pulmonary blood pressure (BP), systemic vascular resistance index, and pulmonary artery wedge pressure, compared with 2 TD or 0.4 TD (p < 0.01); however, pigs in all groups had at least mildly elevated BP. Transcutaneous tissue oxygenation, base excess, and mixed venous oxygen saturation were similar across groups; lactate and methemoglobin were highest with 0.4 TD (p < 0.03). There were no group differences in BF. Over time, myocardial BF increased and hepatic BF decreased in all groups (for 31 TD, p < 0.05); renal BF was unchanged in all groups. There were no group differences in heart, lung, or liver histopathology, and survival. CONCLUSIONS: Although purification from 31% to 2% low-MW Hb content significantly decreased vasoactive responses, further purification to 0.4% had no additional clinically measurable effects in severe HS. If further diminution in HBOC vasoactivity is desired for use in HS, additional technical approaches may be required.

Clinical application of a hemoglobin-based oxygen-carrying solution.

Oxyglobin, a hemoglobin-based oxygen-carrying fluid, is indicated in the treatment of anemia in dogs and may be life saving if compatible red blood cells are not available for transfusion. The colloidal properties of Oxyglobin allow for expansion of the circulatory volume, which may be helpful in patients with hypovolemia, especially hemorrhagic shock. Oxyglobin's colloidal properties can also lead to circulatory overload, with development of pulmonary edema and pleural effusion, however, necessitating careful monitoring of the rate of administration and of the respiratory rate and effort of the patient. Measurement of total or plasma hemoglobin concentration can be used as an aid in monitoring patients receiving Oxyglobin.