Severe hyponatremia with seizures and confirmed mild brain edema by hysteroscopic myomectomy: a case report.

BACKGROUND: Hyponatremia can be developed during hysteroscopic surgery with electrolyte-free irrigation fluid. We experienced severe hyponatremia with postoperative seizures and confirmed mild brain edema. CASE PRESENTATION: A quadragenarian female patient underwent a 2-h hysteroscopic myomectomy with electrolyte-free fluid for uterine distension under general anesthesia. Plasma sodium level of 84.1 mmol/L 100 min after the start of surgery indicated excessive absorption of the irrigation fluid. Acute severe hyponatremia was diagnosed with significant edema in the conjunctiva, lip, and extremities. She was treated with a continuous infusion of hypertonic saline. However, seizures and cerebral edema developed 7 h later. The patient recovered without neurological deficits at postoperative day 2. CONCLUSION: The electrolyte-free irrigation fluid can be absorbed rapidly during hysteroscopic surgery. Its interruption with hyponatremia should be considered against prolonged surgery. Especially under general anesthesia, caution should be exercised because the typical symptoms of hyponatremia such as nausea and confusion are blinded.

Cytokine marker measurement in human neuroblastoma cells with supersensitive and multiplex assay: MUSTag technology.

BACKGROUND: Recently, various sets of protein -biomarkers have been discovered in important diseases such as cancers, brain stroke and heart attack. However, clinical validation is difficult and time-consuming by individual assays or because of very low concentrations at early stages of the diseases. We have developed assay technology through an innovative modification of the immuno-PCR method for the super-sensitive and multiplex detection of target biomarkers. METHODS: In the assay technology, each different oligo-tag simultaneously detects multiplex protein targets with extremely high-level sensitivity in a dose-dependent manner by qRT-PCR (maximum: three plexes). In this study, we measured specific secreted protein concentrations in the culture supernatant of a 24-h culture of transfected SH-SY5Y cells with MUSTag. RESULTS: There was a significant increase in the protein level of tumor necrosis factor (TNF)-α measured with extremely high-level sensitivity (≥10 pg/mL). Compared with negative controls, the levels of TNF-α increased from 16.9 to 28.1 pg/mL (p = 0.011). CONCLUSION: We suggest that our assay technology might be of clinical value in treating patients with cancer, cerebral ischemia, or patients who need a prompt and predictive diagnosis for adequate treatment.

Int6 silencing causes induction of angiogenic factors in neuronal cells via accumulation of hypoxia-inducible factor 2α and decreases brain damage in rats.

We have previously shown that when siRNA against Int6 (siRNA-Int6) was used, hypoxia-inducible factor 2α (HIF2α) activity was stabilized even under normoxic conditions, and the expression of several angiogenic factors was increased. In neuronal tissues, the mechanism underlying angiogenesis remains largely unknown. In the current study, we investigate the role of the tumor suppressor Int6/eIF3e in the regulation of the expression of angiogenic factors in neuronal cells. In addition, we test whether siRNA-Int6 reduces cold-induced brain damage in rats. We used human neuroblastoma SHSY5Y cells transfected with either siRNA-Int6, or a negative control siRNA. Real-time PCR and supersensitive multiplex assay were used to detect gene and protein expression of several angiogenic factors after transfection. For the animal studies, Wistar rats were subjected to brain damage by cold injury, and 50 µg siRNA-Int6, 100 µg siRNA-Int6, or negative control was administrated. At day 7 post-treatment, brain sections were stained and image analysis system was used to determine the damaged area. Our experiments using SHSY5Y cells revealed a significant effect of siRNA-Int6 on the expression of HIF2α but not HIF1α, both at 8 and 24h after transfection. The siRNA-Int6 led to significant up-regulation of angiogenic factors, including vascular endothelial growth factor and platelet-derived growth factor-B, both at the mRNA and protein levels. Furthermore, our animal studies revealed significantly reduced area of cold-induced damage in rats receiving siRNA-Int6, compared to negative controls. Our findings indicate that Int6 act as a hypoxia-independent master switch of angiogenesis in neuronal cells, and that inhibition of Int6 by siRNA may be an effective therapeutic strategy in treating ischemic diseases such as brain ischemia and injury.

[Organ protective effects of volatile anesthetics and perioperative outcomes].

Anesthetic agents, especially, volatile anesthetics are considered to exert organ toxicity such as nephrotoxicity and hepatotoxicity; however, recent aggressive researches explored the beneficial effects of volatile anesthetics as an organ protectant. Ischemic preconditioning is a phenomenon in which single or multiple brief periods of ischemia have been shown to protect the myocardium and brain against prolonged ischemic insult. General anesthesia showed the protection against both ischemic myocardial and brain reperfusion injuries. This phenomenon is called anesthetic preconditioning. Regarding the organ protection, anesthetic preconditioning is one of the useful ways to diverse the organ protective effects not only to heart but also brain. Nowadays, ischemic postconditioning, consisting of repeated brief cycles of ischemia-reperfusion performed immediately after reperfusion following a prolonged ischemic insult, dramatically reduces infarct size in experimental models and such clinical studies are reported. Both preconditioning and postconditioning share the same signal transduction pathway and inhibit the mitochondrial permeability transition (MPT) that leads to either apoptosis or necrosis of myocardium and neuronal cell. Both phenomena look very promising, but we still lack the real evidence for human reserach in terms of the clinical outcome and further analysis is necessary. Neurotoxicities of anesthetic agents are very crucial problems for the patient and they are considered to be due to the activation of IP3 receptor in ER after exposure to volatile anesthetics. Massive release of Ca2+ from ER induces Ca2+ overload leading to mitochondria permeability transition (MPT) and induces apoptosis in the brain or aggravates the neurodegenerative disease. Susceptible mechanisms and beneficial treatment for the toxicity of general anesthesia is considered as a critical subject to discuss and challenge to solve for our future.

Effects of different types of anesthetic agents on cellular protein kinase C-γ dynamics in mouse brain.

BACKGROUND/AIMS: Although protein kinase C-γ (PKC-γ) is a target for the effects of volatile anesthetics, the molecular mechanisms of the kinase function during their action remain unclear. We examined the effects of different types of anesthetics on PKC-γ knockout mice. Furthermore, we investigated the dynamics of the kinase in brain cells obtained from mice anesthetized with these anesthetics. METHODS: We measured the required times for loss of righting reflex (rtfLORR) after administration of isoflurane, sevoflurane, or propofol on PKC-γ knockout mice and compared the times with those of wild-type mice. We also used immunoblotting to investigate the intracellular distribution of PKC-γ and phosphorylated PKC-γ (p-PKC-γ) in brain cell fractions obtained from wild-type mice during the loss of righting reflex induced by these anesthetics. RESULTS: Isoflurane (2.6%) and sevoflurane (3.4%) used at twice the minimum alveolar concentration significantly prolonged the rtfLORRs in PKC-γ knockout mice compared to those in wild-type mice. On the other hand, no significant difference was observed between knockout and wild-type mice treated with propofol (200 mg/kg). Examination of the cellular fractions isolated from volatile anesthetic-treated mouse brains showed that PKC-γ was significantly decreased in the synaptic membrane fraction (P2), whereas p-PKC-γ was significantly increased in P2. There was no significant change in the supernatant fraction (S). In propofol-treated mice, PKC-γ and p-PKC-γ showed no significant changes in P2 or S. CONCLUSION: Our results provide new evidence to support the possibility of the involvement of PKC-γ in the actions of volatile anesthetics.