Building Interest in the Primary Care Specialty Through Enhanced Global Health Experience.

Background An overwhelming majority of matriculating medical students in the USA are keen to deliver quality health care to all people, including the socioeconomically disadvantaged populations in remote, resource-scarce regions nationally and worldwide. Here, we describe a protocol developed to evaluate the interest of our medical students in global health activities. We also examined the relationship between students' interest in global health and readiness to pursue a future career in the primary care specialty. Materials and methods We designed a survey in Qualtrics online software and reached all first-year and third-year medical students between 2019 and 2022 enrolled at the Alabama College of Osteopathic Medicine (ACOM). The survey utilized ordinal scale items to explore the medical students' interest in primary care residency programs, their interest in global health and international travel, and their perceptions of how a range of factors might motivate their desire to participate in global health activities. The study was approved by ACOM's Institutional Review Board (IRB). In order to compare findings from this study with data from other medical schools, we developed constructs using the national aggregate data, in percentages, from matriculants and graduates of Doctor of Osteopathic Medicine (DO) degree-granting medical schools according to gender, published by the American Association of Colleges of Osteopathic Medicine (AACOM). Statistical analysis of national aggregate data was performed using the unpaired t-test. Results Both female and male participants had lived or traveled abroad before starting medical school. Female (98%, n=249) and male (95%, n=140) participants in the first-year cohorts considered helping the underserved population as important or very important as it is related to a career in medicine. Females in the third-year cohorts (97%, n=71) also ranked this statement as important or very important compared to male cohorts (89%, n=31). A higher proportion of females (43%, n=108) compared to males (35%, n=52) in first-year cohorts agreed or strongly agreed that they would likely pursue a residency in primary care. More females (59%, n=43) than males (46%, n=16) in the third-year cohorts agreed or strongly agreed with the same statement. Analysis of the aggregate national data (2009-2022) revealed that the percentage (actual count not available) of female students who planned to practice in underserved/shortage area was higher both at the time of matriculation (M=51%, SD=4%) and before graduation (M=40%, SD=4%) compared to males (matriculation: M=40%, SD=5%; graduation: M=33%, SD=4%) presenting a significant difference (matriculation t(24)=6.7, p<0.0001; graduation t(24)=5.4, p<0.0001). Furthermore, a higher percentage of females at the time of matriculation (M=25%, SD=5%) and graduation (M=40%, SD=6%) planned to practice in the primary care specialties compared to males (matriculation: M=17%, SD=4%; graduation: M=29%, SD=6%) presenting a significant difference (matriculation: t(24)=4.6, p = 0.0001; graduation: t(24)=4.8, p<0.0001). Conclusions Interest in global health activities may be associated with interest in pursuing a future career in the primary care specialty. In this study, more female medical students expressed interest in participating in global health experiences, serving the underserved population domestically and abroad, and expressing interest in primary care than males.

The Effect of Short-Term Exposure to Cadmium on the Expression of Vascular Endothelial Barrier Antigen in the Developing Rat Forebrain and Cerebellum: A Computerized Quantitative Immunofluorescent Study.

Clinical and laboratory studies have shown that environmental exposure to cadmium produces damage to several organs, including bones, lungs, and kidneys. The involvement of cadmium in central nervous system (CNS) disorders has also been widely reported, but the precise pathophysiological mechanism is not yet fully understood. Children who were exposed to cadmium during pregnancy are known to suffer from developmental delays, learning difficulties, attention deficit hyperactivity disorder (ADHD), and other cognitive and neurobehavioral deficits. Results from numerous studies suggest that dysfunction of the blood-brain barrier (BBB) structures is an important step in the neurotoxicity of cadmium. A rat-specific BBB marker protein, the endothelial barrier antigen (EBA), has been previously isolated and classified by Sternberger and others. The mouse IgG1 clone, anti-endothelial barrier antigen (anti-EBA), detects a protein triplet (23.5kDa, 25 kDa, and 30kDa) localized to the luminal surface of central and peripheral nervous system (CNS and PNS) vascular endothelial cells with selective permeability barrier functions. This marker has been widely used for characterizing BBB alterations under demyelinating, inflammatory, and other CNS pathologies. Many studies have been published using the rat model system for studying the neurotoxic effect of acute and chronic exposure to cadmium. We applied the indirect immunofluorescent techniques using the anti-EBA antibody in conjunction with the Olympus cellSens computerized image analysis to detect and quantify the surface areas of BBB-competent microvessel profiles in paraformaldehyde-fixed, paraffin-embedded brains of term-delivered young rats after intraperitoneal injection of a single dose of cadmium chloride. We detected a statistically significant reduction in EBA-positive microvessel surface areas in the forebrain (t = 5.86, df = 1789, p-value < 0.001) and cerebellum (t=73.40, df=1337, p < 0.001) of cadmium-treated rats compared to the normal controls. Thus, this study supports the hypothesis that the EBA is a sensitive and measurable indicator for quantitative assessment of the impact of cadmium exposure in the developing rat brain.

Decibel attenuation of pulsed electromagnetic field (PEMF) in blood and cortical bone determined experimentally and from the theory of ohmic losses.

We studied the PEMF power attenuation in tissues representative of clinical applications (blood and cortical bone) to determine the amount of power available for PEMF purported biological effects. The experimental system consisted of a pair of nearly circular, parallel and coaxial coils separated by a distance of one coil diameter. The power attenuation was measured using a small search coil connected to a digital oscilloscope. The coils were powered by a voltage switch operating at two different frequencies (3.8 and 63 kHz) producing bursts of pulses (numbering 21 and 1619) and triggered at two different frequencies (1.5 and 15 Hz, respectively). The tissue samples were placed inside the coils so as to expose them to either transverse electric field (at the center of coils) or the transverse magnetic field (at the coil wire). The cylindrical coil geometry yielded closed-form expressions for power attenuation based on magnetic diffusion equation and ohmic losses due to bulk tissue magnetic permeability and electrical conductivity. The measured power attenuation at these PEMF frequencies of not more than one decibel (1 dB) was well explained by the theory for the 3.8 kHz but less so for the 63 kHz frequency PEMF. The results provide important insights regarding physical mechanism of weak PEMF power dissipation in tissues.

Exposure of murine cells to pulsed electromagnetic fields rapidly activates the mTOR signaling pathway.

Murine pre-osteoblasts and fibroblast cell lines were used to determine the effect of pulsed electromagnetic field (PEMF) exposure on the production of autocrine growth factors and the activation of early signal transduction pathways. Exposure of pre-osteoblast cells to PEMF minimally increased the amount of secreted TGF-beta after 1 day, but had no significant effects thereafter. PEMF exposure of pre-osteoblast cells also had no effect on the amount of prostaglandin E(2) in the conditioned medium. Exposure of both pre-osteoblasts and fibroblasts to PEMF rapidly activated the mTOR signaling pathway, as evidenced by increased phosphorylation of mTOR, p70 S6 kinase, and the ribosomal protein S6. Inhibition of PI3-kinase activity with the chemical inhibitor LY294002 blocked PEMF-dependent activation of mTOR in both the pre-osteoblast and fibroblast cell lines. These findings suggest that PEMF exposure might function in a manner analogous to soluble growth factors by activating a unique set of signaling pathways, inclusive of the PI-3 kinase/mTOR pathway.

Exposure of mouse preosteoblasts to pulsed electromagnetic fields reduces the amount of mature, type I collagen in the extracellular matrix.

We tested the hypothesis that exposure of a mouse preosteoblast cell line to pulsed electromagnetic fields (PEMF) would affect components of the extracellular matrix. We report that exposure of MC3T3-E1 cells to a single PEMF waveform significantly reduced the amount of mature, alpha1(I) collagen in the extracellular matrix (ECM) and the conditioned medium, without affecting the amount of total ECM protein. This decrease was not due to changes in the steady-state level of Col1A1 mRNA or to degradation of mature collagen. We then tested the effect of three distinct PEMF waveforms, two orthogonal coil orientations, and two waveform amplitude levels on the amount of alpha1(I) collagen in the conditioned medium. A sequence of factorial ANOVAs and stepwise regression modeling revealed that the period (duration) of the individual pulses accounted for a significant proportion of the variance associated with the amount of alpha1(I) collagen in the conditioned medium. The total variance accounted for, however, was small (R(2)=0.155, p<0.001 and R(2)=0.172, p<0.001, in the horizontal and vertical orientations, respectively). The positive and negative regression coefficients for the coil orientations revealed that the influence of pulse period was significantly different for the orthogonal coil orientations (p<0.001). The findings imply that the dominant influence of PEMF on the amount of mature, alpha1(I) collagen in the ECM is related to variables other than those expressed in the time-amplitude domain. The results provide objective direction toward identifying waveform characteristics that contribute to the observed between-waveform differences with regard to collagen. Advances in this area may lead toward improving waveforms and waveform delivery protocols.

In vivo longitudinal assessment of bone resorption in a fibular osteotomy model using micro-computed tomography.

Longitudinal in vivo micro-computerized tomography (CT) imaging was used to monitor bone resorption in a rat fibula osteotomy model. Quantitative image post-processing techniques were developed for spatially aligning the longitudinal data sets. Nominal length and bone volume in the proximal and distal segments of the fibula after the osteotomy were measured, and quantitative comparisons of bone loss over a 13-week period post-surgery were made in five individual rats. A significant decrease in nominal length and bone volume of the distal segment was observed 13 weeks post surgery. A significant decrease in bone volume was also observed in the proximal segment. However, no change in nominal length was observed for the proximal segment of the fibula. This study illustrates the power of this non-invasive technology to measure in vivo small changes in bone length and volume using just a small cohort of animals.

Pulsed electromagnetic field treatments enhance the healing of fibular osteotomies.

This study tested the hypothesis that pulsed electromagnetic field (PEMF) treatments augment and accelerate the healing of bone trauma. It utilized micro-computed tomography imaging of live rats that had received bilateral 0.2 mm fibular osteotomies (approximately 0.5% acute bone loss) as a means to assess the in vivo rate dynamics of hard callus formation and overall callus volume. Starting 5 days post-surgery, osteotomized right hind limbs were exposed 3 h daily to Physio-Stim PEMF, 7 days a week for up to 5 weeks of treatment. The contralateral hind limbs served as sham-treated, within-animal internal controls. Although both PEMF- and sham-treatment groups exhibited similar onset of hard callus at approximately 9 days after surgery, a 2-fold faster rate of hard callus formation was observed thereafter in PEMF-treated limbs, yielding a 2-fold increase in callus volume by 13-20 days after surgery. The quantity of the new woven bone tissue within the osteotomy sites was significantly better in PEMF-treated versus sham-treated fibulae as assessed via hard tissue histology. The apparent modulus of each callus was assessed via a cantilever bend test and indicated a 2-fold increase in callus stiffness in the PEMF-treated over sham-treated fibulae. PEMF-treated fibulae exhibited an apparent modulus at the end of 5-weeks that was approximately 80% that of unoperated fibulae. Overall, these data indicate that Physio-Stim PEMF treatment improved osteotomy repair. These beneficial effects on bone healing were not observed when a different PEMF waveform, Osteo-Stim, was used. This latter observation demonstrates the specificity in the relationship between waveform characteristics and biological outcomes.

Bone mass is preserved in a critical-sized osteotomy by low energy pulsed electromagnetic fields as quantitated by in vivo micro-computed tomography.

The effectiveness of non-invasive pulsed electromagnetic fields (PEMF) on stimulating bone formation in vivo to augment fracture healing is still controversial, largely because of technical ambiguities in data interpretation within several previous studies. To address this uncertainty, we implemented a rigorously controlled, blinded protocol using a bilateral, mid-diaphyseal fibular osteotomy model in aged rats that achieved a non-union status within 3-4 weeks post-surgery. Bilateral osteotomies allowed delivery of a PEMF treatment protocol on one hind limb, with the contralateral limb representing a within-animal sham-treatment. Bone volumes in both PEMF-treated and sham-treated fibulae were assessed simultaneously in vivo using highly sensitive, high-resolution micro-computed tomography (microCT) over the course of treatment. We found a significant reduction in the amount of time-dependent bone volume loss in PEMF-treated, distal fibular segments as compared to their contralateral sham-treated bones. Osteotomy gap size was significantly smaller in hind limbs exposed to PEMF over sham-treatment. Therefore, our data demonstrate measurable biological consequences of PEMF exposure on in vivo bone tissue.

Magnetic field visualization in applications to pulsed electromagnetic field stimulation of tissues.

Electromagnetic field visualization is important in multidisciplinary research on the molecular basis of therapeutic effects of pulsed electromagnetic fields (PEMF). We have compared classic PEMF representations by two-dimensional field lines and field magnitude contour plots with a field representation using three-dimensional field isosurfaces. Field simulations were performed for a clinically approved Spinal-Stim Lite system (Orthofix Inc., McKinney, TX). The relatively simple coil system geometry and the predominantly dielectric properties of the surrounding medium (air and human connective tissue) allowed us to develop analytical expressions for the field. The field model was validated by comparison with experimentally measured field values, and with values calculated using a commercial finite-element analysis software package. Two-dimensional field representations by field lines and field contour plots were less intuitive than three-dimensional field isosurface representations to members of the group without an engineering background. Field isosurfaces, represented as three-dimensional solids, allowed for direct visualization of PEMF targeting of individual organs (lumbar spine), the extent of the therapeutic field value, and the directional field characteristics. The dynamic characteristic of the field was well illustrated by a sequence of field isosurfaces corresponding to the evolution with time of the electric current waveform (sawtooth) powering the coils. The isosurface representation of the field can be extended to any three-dimensional coil system geometry using plotting capabilities of current computer algebra software packages.