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Browsing by Author "John, Quincy E."
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Item Are Surgeons Behind the Scientific Eight Ball: Delayed Acquisition of the NIH K08 Mentored Career Development Award(Elsevier, 2020-02) Hosfield, Brian D.; John, Quincy E.; Seiler, Kristen M.; Good, Misty; Dunnington, Gary L.; Markel, Troy A.; Surgery, School of MedicineBackground: Surgery residents complete their research training early in residency. Non-surgical trainees typically have research incorporated toward the last two years of their fellowship, conferring an advantage to apply for grants with recent research experience and preliminary data. Methods: The NIH RePORTER database was queried for K08 awardees trained in medicine, pediatrics, and surgery from 2013 to 2017. 406 K08 recipients were identified and time from completion of clinical training to achieving a K08 award was measured. Data were compared using ANOVA and expressed as mean. P < 0.05 was considered significant. Results: Surgeons took longer to obtain a K08 than those trained in internal medicine (surgery = 3.7 years, internal medicine = 2.58 years p < 0.0001)). All K08 recipients without a PhD took longer to obtain a K08 than recipients with a PhD (MD = 3.50 years and MD/PhD = 2.42 years (p=<0.0001). Conclusions: Surgeons take longer to achieve a K08 award than clinicians trained in internal medicine, possibly due to an inherent disadvantage in training structure.Item Mesenchymal stem cells promote mesenteric vasodilation through hydrogen sulfide and endothelial nitric oxide(American Physiological Society, 2019-09-24) Te Winkel, Jan; John, Quincy E.; Hosfield, Brian D.; Drucker, Natalie A.; Das, Amitava; Olson, Ken R.; Markel, Troy A.; Surgery, School of MedicineMesenteric ischemia is a devastating process that can result in intestinal necrosis. Mesenchymal stem cells (MSCs) are becoming a promising treatment modality. We hypothesized that 1) MSCs would promote vasodilation of mesenteric arterioles, 2) hydrogen sulfide (H2S) would be a critical paracrine factor of stem cell-mediated vasodilation, 3) mesenteric vasodilation would be impaired in the absence of endothelial nitric oxide synthase (eNOS) within the host tissue, and 4) MSCs would improve the resistin-to-adiponectin ratio in mesenteric vessels. H2S was measured with a specific fluorophore (7-azido-3-methylcoumarin) in intact MSCs and in cells with the H2S-producing enzyme cystathionine β synthase (CBS) knocked down with siRNA. Mechanical responses of isolated second- and third-order mesenteric arteries (MAs) from wild-type and eNOS knockout (eNOSKO) mice were monitored with pressure myography, after which the vessels were snap frozen and later analyzed for resistin and adiponectin via multiplex beaded assay. Addition of MSCs to the myograph bath significantly increased vasodilation of norepinephrine-precontracted MAs. Knockdown of CBS in MSCs decreased H2S production by MSCs and also decreased MSC-initiated MA dilation. MSC-initiated vasodilation was further reduced in eNOSKO vessels. The MA resistin-to-adiponectin ratio was higher in eNOSKO vessels compared with wild-type. These results show that MSC treatment promotes dilation of MAs by an H2S-dependent mechanism. Furthermore, functional eNOS within the host mesenteric bed appears to be essential for maximum stem cell therapeutic benefit, which may be attributable, in part, to modifications in the resistin-to-adiponectin ratio. NEW & NOTEWORTHY Stem cells have been shown to improve survival, mesenteric perfusion, and histological injury scores following intestinal ischemia. These benefits may be due to the paracrine release of hydrogen sulfide. In an ex vivo pressure myography model, we observed that mesenteric arterial dilation improved with stem cell treatment. Hydrogen sulfide release from stem cells and endothelial nitric oxide synthase within the vessels were critical components of optimizing stem cell-mediated mesenteric artery dilation.