Preoperative comorbidity and modes of failure in revision hip arthroplasty: a single-surgeon series in a tertiary referral centre.

Revision hip arthroplasty is associated with higher morbidity post-operatively than primary surgery. We reviewed data on 102 consecutive patients (124 procedures) undergoing revision hip arthroplasty by a single surgeon from January 2005 to June 2009 in 2 institutions. Indications of failure: 62% aseptic loosening, 15% infection, 11.5% fracture, 10.6% dislocation or instability and 0.9% implant failure. Preoperative comorbidities: 28.4% cardiac, 4% respiratory and 6.8% diabetic. Morbidity: 3.9% complication rate (5 of 124 procedures). 73.5 median age and 46% over 75 years old. Modes of failure in our population leading to revision hip arthroplasty are similar to other studies. We showed a low morbidity following revision hip arthroplasty despite significant preoperative comorbidities and a high proportion of elderly patients. In conclusion, gender, age (>75) and preoperative comorbidities should not deter from revision surgery.

Sleep loss does not aggravate the deteriorating effect of hypoglycemia on neurocognitive function in healthy men.

INTRODUCTION: Sleep deprivation (SD) impairs neurocognitive functions. Assuming that this effect is mediated by reduced cerebral glucose supply due to prolonged wakefulness inducing a progressive depletion of cerebral glycogen stores, we hypothesized that short-term sleep loss amplifies the deteriorating effects of acute hypoglycemia on neurocognitive functions. METHODS: Seven healthy men were tested in a randomized and balanced order on 3 different conditions spaced 2 weeks apart. After a night of total SD (total SD), 4.5h of sleep (partial SD) and a night with 7h of regular sleep (regular sleep), subjects were exposed to a stepwise hypoglycemic clamp experiment. Reaction time (RT) and auditory evoked brain potentials (AEP) were assessed during a euglycemic baseline period and at the end of the clamp (blood glucose at 2.5mmol/l). RESULTS: During the euglycemic baseline, amplitude of the P3 component of the AEP was lower after total SD than after partial SD (9.2+/-3.2microV vs. 16.6+/-2.9microV; t(6)=3.2, P=0.02) and regular sleep (20.2+/-2.1microV; t(6)=18.8, P<0.01). Reaction time was longer after total SD in comparison to partial SD (367+/-45ms vs. 304+/-36ms; t(6)=2.7, P=0.04) and to regular sleep (322+/-36ms; t(6)=2.41, P=0.06) while there was no difference between partial SD and regular sleep condition (t(6)=0.60, P=0.57). Hypoglycemia decreased P3 amplitude by 11.2+/-4.1microV in the partial SD condition (t(6)=2.72, P=0.04) and by 9.3+/-0.7microV in the regular sleep condition (t(6)=12.51, P<0.01), but did not further reduce P3 amplitude after total SD (1.8+/-3.9microV; t(6)=0.46, P=0.66). Thus, at the end of hypoglycemia P3 amplitudes were similar across the 3 conditions (F(2,10)=0.89, P=0.42). RT generally showed a similar pattern with a significant prolongation due to hypoglycemia after partial SD (+42+/-12ms; t(6)=3.39, P=0.02) and regular sleep (+37+/-10ms; t(6)=3.53, P=0.01), but not after total SD (+15+/-16; t(6)=0.97, P=0.37), resulting in similar values at the end of hypoglycemia (F(1,6)=1.01, P=0.36). CONCLUSIONS: One night of total SD deteriorates neurocognitive function as reflected by indicators of attentive stimulus processing, but does not synergistically aggravate the impairing influence of acute hypoglycemia. The findings are not consistent with the view that neurocognitive deteriorations after SD result from challenged cerebral glucose metabolism.

Sleep loss alters basal metabolic hormone secretion and modulates the dynamic counterregulatory response to hypoglycemia.

CONTEXT: Sleep loss has immediate effects on metabolic function that in the long run may contribute to the development of obesity and type 2 diabetes. OBJECTIVE: Our objective was to explore the neuroendocrine mechanisms mediating the acute effects of sleep deprivation on blood glucose regulation under basal and hypoglycemic conditions. METHODS: In a randomized, crossover study in 10 healthy young men, plasma concentrations of relevant hormones were examined during basal rest, a subsequent stepwise hypoglycemic clamp after one night of total sleep deprivation (SD) and one night of regular sleep. RESULTS: Basal glucagon concentrations were decreased (P = 0.022) and C-peptide levels were slightly reduced after SD (P = 0.085), compared with regular sleep. During hypoglycemia after SD, the glucagon increase relative to baseline was enhanced (P = 0.034) and the relative decrease in C-peptide was reduced (P = 0.013). Also, the relative increase in norepinephrine was reduced (P = 0.031). SD did not affect epinephrine, ACTH, cortisol, lactate, beta-hydroxybutyrate, or nonesterified fatty acids during hypoglycemia, but overall, plasma nonesterified fatty acid levels were reduced after SD (P = 0.009). SD markedly increased rated hunger during basal rest (P < 0.008), resulting in a dampened relative increase during hypoglycemia (P < 0.009). Unexpectedly, despite distinct alterations in basal secretory activity, the absolute amplitude of hormonal counterregulation and hunger responses to hypoglycemia was not affected by SD. CONCLUSION: Short-term SD distinctly alters hormonal glucose regulation, affecting especially pancreatic islet secretion, and also increases hunger. Immediate perturbations in the dynamic regulation of energy metabolism caused by acute sleep curtailment may contribute to the association between chronic sleep loss and metabolic disorders.