Oscar E. Suman scite author profile

Objective To improve clinical outcome and to determine new treatment options, we studied the pathophysiologic response postburn in a large prospective, single center, clinical trial. Summary Background Data A severe burn injury leads to marked hypermetabolism and catabolism, which are associated with morbidity and mortality. The underlying pathophysiology and the correlations between humoral changes and organ function have not been well delineated. Methods Two hundred forty-two severely burned pediatric patients [>30% total body surface area (TBSA)], who received no anabolic drugs, were enrolled in this study. Demographics, clinical data, serum hormones, serum cytokine expression profile, organ function, hypermetabolism, muscle protein synthesis, incidence of wound infection sepsis, and body composition were obtained throughout acute hospital course. Results Average age was 8 ± 0.2 years, and average burn size was 56 ± 1% TBSA with 43 ± 1% third-degree TBSA. All patients were markedly hypermetabolic throughout acute hospital stay and had significant muscle protein loss as demonstrated by a negative muscle protein net balance (−0.05% ± 0.007 nmol/100 mL leg/min) and loss of lean body mass (LBM) (−4.1% ± 1.9%); P < 0.05. Patients lost 3% ± 1% of their bone mineral content (BMC) and 2 ± 1% of their bone mineral density (BMD). Serum proteome analysis demonstrated profound alterations immediately postburn, which remained abnormal throughout acute hospital stay; P < 0.05. Cardiac function was compromised immediately after burn and remained abnormal up to discharge; P < 0.05. Insulin resistance appeared during the first week postburn and persisted until discharge. Patients were hyperinflammatory with marked changes in IL-8, MCP-1, and IL-6, which were associated with 2.5 ± 0.2 infections and 17% sepsis. Conclusions In this large prospective clinical trial, we delineated the complexity of the postburn pathophysiologic response and conclude that the postburn response is profound, occurring in a timely manner, with derangements that are greater and more protracted than previously thought.

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Long-Term Persistance of the Pathophysiologic Response to Severe Burn Injury

Jeschke

et al. 2011

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BackgroundMain contributors to adverse outcomes in severely burned pediatric patients are profound and complex metabolic changes in response to the initial injury. It is currently unknown how long these conditions persist beyond the acute phase post-injury. The aim of the present study was to examine the persistence of abnormalities of various clinical parameters commonly utilized to assess the degree hypermetabolic and inflammatory alterations in severely burned children for up to three years post-burn to identify patient specific therapeutic needs and interventions.Methodology/Principal FindingsPatients: Nine-hundred seventy-seven severely burned pediatric patients with burns over 30% of the total body surface admitted to our institution between 1998 and 2008 were enrolled in this study and compared to a cohort non-burned, non-injured children. Demographics and clinical outcomes, hypermetabolism, body composition, organ function, inflammatory and acute phase responses were determined at admission and subsequent regular intervals for up to 36 months post-burn. Statistical analysis was performed using One-way ANOVA, Student's t-test with Bonferroni correction where appropriate with significance accepted at p<0.05. Resting energy expenditure, body composition, metabolic markers, cardiac and organ function clearly demonstrated that burn caused profound alterations for up to three years post-burn demonstrating marked and prolonged hypermetabolism, p<0.05. Along with increased hypermetabolism, significant elevation of cortisol, catecholamines, cytokines, and acute phase proteins indicate that burn patients are in a hyperinflammatory state for up to three years post-burn p<0.05.ConclusionsSevere burn injury leads to a much more profound and prolonged hypermetabolic and hyperinflammatory response than previously shown. Given the tremendous adverse events associated with the hypermetabolic and hyperinflamamtory responses, we now identified treatment needs for severely burned patients for a much more prolonged time.

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Exercise‐induced diaphragmatic fatigue in healthy humans.

Johnson¹,

Babcock²,

Suman³

et al. 1993

The Journal of Physiology

408

315

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SUMMARY1. Twelve healthy subjects (33 + 3 years) with a variety of fitness levels (maximal oxygen uptake (VO2 max) = 61+4 ml kg-1 min-', range , exercised at 95 and 85 % V02, max to exhaustion (mean time = 14 + 3 and 31+8 min, expired ventilation (VE) over final minute of exercise = 149+9 and 126 + 10 1 min-').2. Bilateral transcutaneous supramaximal phrenic nerve stimulation (BPNS) was performed before and immediately after exercise at four lung volumes, and 400 ms tetanic stimulations were performed at 10 and 20 Hz. The coefficients of variation of repeated measurements for the twitch transdiaphragm pressures (Pdi) were +7-10 % and for compound muscle action potentials (M wave) ± 10-15 %. 5. The fPdi min-' and the fP. min-' (PO, oesophageal pressure) rose together from rest through the fifth to tenth minute of exercise, after which fPdi min-' plateaued even though fPO min-', VE and inspiratory flow rate all continued to rise substantially until exercise terminated. Thus, the relative contribution of the diaphragm to total respiratory motor output was progressively reduced with exercise duration.6. We conclude that significant diaphragmatic fatigue is caused by the ventilatory requirements imposed by heavy endurance exercise in healthy persons with a variety of fitness levels. The magnitude of the fatigue and the likelihood of its occurrence increases as the relative intensity of the exercise exceeds 85 % of V02 max,

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The metabolic stress response to burn trauma: current understanding and therapies

et al. 2016

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Summary Severe burns incur a profound stress response, which is unrivaled in terms of its magnitude and duration. Recent evidence suggests that the pathophysiological stress response to severe burns persists for several years post injury. Thus, there is a pressing need for novel strategies that mitigate this response and restore normal metabolic function in burn survivors. This is the first installment of a three-part series exploring the stress response to severe burn trauma. In this article we aim to distill the current knowledge pertaining to the stress response to burn trauma, highlighting recent developments and important knowledge gaps that need to be pursued in order to develop novel therapeutic strategies which improve outcomes in burn survivors.

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Oscar E. Suman

Pathophysiologic Response to Severe Burn Injury

Long-Term Persistance of the Pathophysiologic Response to Severe Burn Injury

Exercise‐induced diaphragmatic fatigue in healthy humans.

The metabolic stress response to burn trauma: current understanding and therapies

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