The effects of isolated and integrated 'core stability' training on athletic performance measures: a systematic review.

BACKGROUND: Core stability training, operationally defined as training focused to improve trunk and hip control, is an integral part of athletic development, yet little is known about its direct relation to athletic performance. OBJECTIVE: This systematic review focuses on identification of the association between core stability and sports-related performance measures. A secondary objective was to identify difficulties encountered when trying to train core stability with the goal of improving athletic performance. DATA SOURCES: A systematic search was employed to capture all articles related to athletic performance and core stability training that were identified using the electronic databases MEDLINE, CINAHL and SPORTDiscus™ (1982-June 2011). STUDY SELECTION: A systematic approach was used to evaluate 179 articles identified for initial review. Studies that performed an intervention targeted toward the core and measured an outcome related to athletic or sport performances were included, while studies with a participant population aged 65 years or older were excluded. Twenty-four in total met the inclusionary criteria for review. STUDY APPRAISAL AND SYNTHESIS METHODS: Studies were evaluated using the Physical Therapy Evidence Database (PEDro) scale. The 24 articles were separated into three groups, general performance (n = 8), lower extremity (n = 10) and upper extremity (n = 6), for ease of discussion. RESULTS: In the majority of studies, core stability training was utilized in conjunction with more comprehensive exercise programmes. As such, many studies saw improvements in skills of general strengths such as maximum squat load and vertical leap. Surprisingly, not all studies reported measurable increases in specific core strength and stability measures following training. Additionally, investigations that targeted the core as the primary goal for improved outcome of training had mixed results. LIMITATIONS: Core stability is rarely the sole component of an athletic development programme, making it difficult to directly isolate its affect on athletic performance. The population biases of some studies of athletic performance also confound the results. CONCLUSIONS: Targeted core stability training provides marginal benefits to athletic performance. Conflicting findings and the lack of a standardization for measurement of outcomes and training focused to improve core strength and stability pose difficulties. Because of this, further research targeted to determine this relationship is necessary to better understand how core strength and stability affect athletic performance.

Myocardial function after fetal cardiac bypass in an ovine model.

OBJECTIVE: Fetal cardiac surgery might improve the prognosis of certain complex congenital heart defects that have significant associated mortality and morbidity in utero or after birth. An important step in translating fetal cardiac surgery is identifying potential mechanisms leading to myocardial dysfunction after bypass. The hypothesis was that fetal cardiac bypass results in myocardial dysfunction, possibly because of perturbation of calcium cycling and contractile proteins. METHODS: Midterm sheep fetuses (n = 6) underwent 30 minutes of cardiac bypass and 120 minutes of monitoring after bypass. Sonomicrometric and pressure catheters inserted in the left and right ventricles measured myocardial function. Cardiac contractile and calcium cycling proteins, along with calpain, were analyzed by means of immunoblotting. RESULTS: Preload recruitable stroke work (slope of the regression line) was reduced at 120 minutes after bypass (right ventricle: baseline vs 120 minutes after bypass, 38.6 ± 6.8 vs 20.4 ± 4.8 [P = .01]; left ventricle: 37 ± 7.3 vs 20.6 ± 3.9, respectively [P = .01]). Tau (in milliseconds), a measure of diastolic relaxation, was increased in both ventricles (right ventricle: baseline vs 120 minutes after bypass, 32.7 ± 4.5 vs 67.8 ± 9.4 [P < .01]); left ventricle: 26.1 ± 3.2 vs 63.2 ± 11.2, respectively [P = .01]). Cardiac output was lower and end-diastolic pressures were higher in the right ventricle, but not in the left ventricle, after bypass compared with baseline values. Right ventricular troponin I was degraded by increased calpain activity, and protein levels of sarco(endo)plasmic reticulum calcium ATPase were reduced in both ventricles. CONCLUSIONS: Fetal cardiac bypass was associated with myocardial dysfunction and disruption of calcium cycling and contractile proteins. Minimizing myocardial dysfunction after cardiac bypass is important for successful fetal surgery to repair complex congenital heart defects.

Application of near-infrared spectroscopy during fetal cardiac surgery.

BACKGROUND: Near-infrared spectroscopy (NIRS) has been shown to provide reliable noninvasive monitoring of regional oxygenation in a variety of clinical settings. We set out to test its feasibility as a monitor of fetal and placental oxygenation during fetal cardiac surgery. MATERIALS AND METHODS: Six ovine fetuses from 98-110 ds gestation were placed on fetal bypass for 30 min and followed post-bypass for 2 h. A NIRS probe (MI INVOS 5100B; Somanetics, Troy, MI) was placed on the pregnant uterine horn during and after fetal surgery. NIRS values were compared with blood gas values obtained by direct sampling from umbilical circulation. RESULTS: NIRS values positively correlated with umbilical venous oxygen saturation (R(2)=0.891, P<0.01) and partial oxygen pressure values (R(2)=0.810, P<0.01). NIRS values also correlated to a lesser extent with umbilical venous pH and pCO(2), and fetal arterial pH, pO(2), and oxygen saturation. CONCLUSIONS: This is the first report of application of NIRS in the setting of fetal surgery. NIRS permits noninvasive assessment of placental oxygen saturation and pO(2). This technology is a simple and useful tool for real-time monitoring of oxygen delivery to the fetus during maternal-fetal cardiac interventions and of overall well-being of the fetal-placental unit.

Fetal right ventricular myocardial function is better preserved by fibrillatory arrest during fetal cardiac bypass.

BACKGROUND: Protection and preservation of fetal myocardial function are important for successful fetal intracardiac repair. Our objective was to determine fetal biventricular cardiac performance after two cardiac-arrest techniques. METHODS: Three groups of midterm ovine fetuses underwent 90-minute bypass. A control group (no arrest shams, n = 3), and two groups that included 20 minutes of arrest, using fibrillatory (n = 3) or blood cardioplegia (n = 3), were compared. Blood cardioplegia consisted of 4:1 cold blood to crystalloid solution induction every 10 minutes, followed by a warm shot terminal dose before clamp removal. Myocardial function variables from biventricular intracardiac pressure catheters, and 3-axes cardiac sonomicrometry, fetal hemodynamics, and arterial blood gases were continuously recorded. Fetal myocardium was collected for troponin-I analysis at 90 minutes. Statistical analysis was by two-way analysis of variance for repeated measures. RESULTS: Compared with sham, right ventricular myocardial contractility was reduced with plegia but not fibrillation at 90 minutes after arrest: dP/dt max (511 ± 347 vs 1208 ± 239, p < 0.01) and preload-recruitable stroke work (7.2 ± 8.5 vs 32.3 ± 14.6, p < 0.01). Right ventricular end diastolic pressure-volume relationship (ventricular stiffness) worsened by 90 minutes for plegia vs fibrillation (0.84 ± 0.18 vs 0.25 ± 0.16, p < 0.05). There were no differences in left ventricle performance between groups. Fetal heart rate increased in shams by 30 minutes after arrest compared with both arrest groups (p < 0.05). Right ventricular troponin-I degradation increased with plegia, but not fibrillation, compared with sham (p < 0.05). CONCLUSIONS: In vivo, fetal right ventricular contractile function deteriorates with a common blood-plegia regimen. Fibrillatory arrest better preserves right ventricular function, the dominant ventricle in fetal life, for short arrest periods.