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  • Medeiros Patrick posted an update 5 hours, 57 minutes ago

    The changes incorporated to the algorithms provide up-to-date and easy-to-use guidelines to treat patients with IBD.

    The objectives of this work were to evaluate demographic data, healing rate, recurrence rate, amputation rate and death rate of patients with diabetic foot ulcers (DFUs) treated in a Québec outpatient diabetic foot ulcer multidisciplinary clinic. Another objective was to determine factors associated with higher ulcer recurrence.

    We conducted a retrospective cohort study of adults with diabetes with a DFU referred to a Québec City diabetic foot clinic between December 1, 2013 and May 1, 2019. The primary outcome was recurrence rate at 6 months after first ulcer healing. We also evaluated the recurrence rate at 12 months, mean and median time for ulcer healing, mean and median time before recurrence after first ulcer healing, amputation rate, mortality rate and factors associated with DFU recurrence.

    Of the 85 patients included in the study, 26 (37.1%) and 36 (54.4%) had DFU recurrence at 6months and 12 months, respectively, after first ulcer healing. Mean healing time from first consultation in the ulcer clinic was 19.64±21.02 weeks. Of the patients, 36.9% patients underwent lower limb amputation and 30.6% died during follow up. Both previous history of a DFU before first consultation and amputation after first DFU consultation were statistically significant risk factors for DFU recurrence at 12months.

    DFU recurrence was significantly higher in patients with a past history of DFU before the first one evaluated in the diabetic foot clinic and a previous history of amputation. Thus, systematic follow up should be done specifically with these patients.

    DFU recurrence was significantly higher in patients with a past history of DFU before the first one evaluated in the diabetic foot clinic and a previous history of amputation. Thus, systematic follow up should be done specifically with these patients.The objectives of this review were to 1) examine recent strategies and component interventions used to overcome therapeutic inertia in type 2 diabetes mellitus (T2DM), 2) map strategies to the causes of therapeutic inertia they target and 3) identify causes of therapeutic inertia in T2DM that have not been targeted by recent strategies. A systematic search of the literature published from January 2014 to December 2019 was conducted to identify strategies targeting therapeutic inertia in T2DM, and key strategy characteristics were extracted and summarized. The search identified 46 articles, employing a total of 50 strategies aimed at overcoming therapeutic inertia. Strategies were composed of an average of 3.3 interventions (range, 1 to 10) aimed at an average of 3.6 causes (range, 1 to 9); most (78%) included a type of educational strategy. Most strategies targeted causes of inertia at the patient (38%) or health-care professional (26%) levels only and 8% targeted health-care-system-level causes, whereas 28% targeted causes at multiple levels. No strategies focused on patients’ attitudes toward disease or lack of trust in health-care professionals; none addressed health-care professionals’ concerns over costs or lack of information on side effects/fear of causing harm, or the lack of a health-care-system-level disease registry. Strategies to overcome therapeutic inertia in T2DM commonly employed multiple interventions, but novel strategies with interventions that simultaneously target multiple levels warrant further study. Although educational interventions are commonly used to address therapeutic inertia, future strategies may benefit from addressing a wider range of determinants of behaviour change to overcome therapeutic inertia.

    In individuals with type 1 diabetes (T1D), changes in blood glucose (BG) during high-intensity interval exercise (HIIE) are smaller than those observed during aerobic exercise. Study outcomes, however, have been variable, with some demonstrating significant BG decreases and others showing BG increases. This study compared BG outcomes between fasting (AME) and postprandial (PME) HIIE in T1D to test the hypothesis that AME would produce a BG increase, yet PME would cause BG to decline.

    Twelve (6 men and 6 women) physically active individuals with T1D performed two 45-minute exercise sessions (AME at 700 AM, PME at 500 PM) in random order, separated by at least 48 hours. Sessions consisted of a 10-minute warmup (50%VO

    ), followed by 10-second sprints every 2 minutes for 24 minutes, and then an 11-minute cooldown. Capillary glucose was measured pre- and postexercise, and then 60 minutes postexercise. Interstitial glucose was recorded for 24 hours postexercise using continuous glucose monitoring.

    AME caused capillary glucose to increase (from 7.6±1.4 to 9.2±2.9 mmol/L during exercise, and 9.9±2.8 mmol/L in recovery), whereas PME produced a decline in capillary glucose (from 9.9±3.1 to 9.5±3.4 mmol/L during exercise and 8.9±2.7 mmol/L during recovery; time× treatment interaction, p=0.014). PME was associated with a higher frequency of hyperglycemic events in the 6 hours and overnight (midnight to 600 AM) after exercise.

    Fasting HIIE results in a different BG trajectory than postprandial exercise in T1D, and may be beneficial for hypoglycemia avoidance during exercise.

    Fasting HIIE results in a different BG trajectory than postprandial exercise in T1D, and may be beneficial for hypoglycemia avoidance during exercise.

    A parental history of major depressive disorder (MDD) is an established risk factor for MDD in youth, and clarifying the mechanisms related to familial risk transmission is critical. Aberrant reward processing is a promising biomarker of MDD risk; accordingly, the aim of this study was to test behavioral measures of reward responsiveness and underlying frontostriatal resting activity in healthy adolescents both with (high-risk) and without (low-risk) a maternal history of MDD.

    Low-risk and high-risk 12- to 14-year-old adolescents completed a probabilistic reward task (n= 74 low-risk, n= 27 high-risk) and a resting-state functional magnetic resonance imaging scan (n= 61 low-risk, n= 25 high-risk). Group differences in response bias toward reward and resting ventral striatal and medial prefrontal cortex (mPFC) fractional amplitude of low-frequency fluctuations (fALFFs) were examined. selleck products Computational modeling was applied to dissociate reward sensitivity from learning rate.

    High-risk adolescents showed a blunted response bias compared with low-risk adolescents.

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