Transient paraplegia due to subarachnoid haemorrhage following spinal anaesthesia.

Spinal subarachnoid haemorrhage is a rare complication of spinal anaesthesia, especially following atraumatic lumbar puncture and in the absence of coagulopathies. The initial presentation of spinal subarachnoid haemorrhage is variable and paraplegia with full recovery within a few hours is rare. Bleeding can extend into the intracranial subarachnoid space, but there are only a few reports of symptomatic intracranial and spinal subarachnoid haemorrhage after spinal anaesthesia. We report co-existing spinal subarachnoid haemorrhage and intracranial subarachnoid haemorrhage after atraumatic spinal anaesthesia in a 69-year-old woman without a coagulopathy. The day after surgery she developed flaccid paraplegia that spontaneously resolved in a few hours. Magnetic resonance imaging demonstrated subarachnoid high signal intensity from T11-S2, consistent with spinal subarachnoid haemorrhage. On the same day the patient complained of severe headache which was later followed by diplopia. Neurological imaging studies revealed diffuse distribution of blood in the subarachnoid space but no intracranial vascular malformations. At the time of diagnosis spontaneous recovery of spinal symptoms had already begun and the clinical manifestations eventually resolved with conservative management. The possibility of an intracranial haemorrhage should always be considered when spinal subarachnoid haemorrhage is identified, even in cases of uncomplicated spinal anaesthesia in patients with no known risk factors for spinal haemorrhage.

Indices of muscular damage in the perioperative period of peripheral revascularization procedures.

AIM: We evaluated the perioperative levels of plasma myoglobin (Mb) and creatine kinase (CK) in patients submitted to peripheral revascularization surgery for a variety of conditions. METHODS, DESIGN AND SETTING: Observational study in a surgical ward of a community hospital. subjects: 50 consecutive patients were included in the study: 30 were admitted for elective peripheral revascularization (Group 1), 10 for urgent peripheral revascularization (Group 2), and 10 for major elective abdominal surgery with minimal risk of rhabdomyolysis. These latter patients served as Control Group. INTERVENTIONS: CK and Mb levels were measured immediately before intervention, 24 and 48 h postoperatively, and were compared in each group. Patients with CK >1,000 UI/l within this period were submitted to standard prophylaxis of acute renal failure (ARF), and further monitored. RESULTS: Preoperative values of CK and Mb were normal in Group 1 and Control Group, but not in Group 2. After the intervention, CK and Mb levels increased in all groups, although in a different degree. This increase was maximal in Group 2, where 9 patients showed CK >1,000 UI/l within the first 48 postoperative hours, and were submitted to ARF prophylaxis. In Group 1 CK and Mb values increased moderately, and maximal CK values were below 1,000 UI/l in all cases. The postoperative increase in CK and Mb values was minimal in Control Group, where these parameters were already in the normal range 48 hours after the intervention. CONCLUSIONS: Persistently increased CK and Mb at 48 h after a peripheral revascularization procedure are consistent with a significant ischemia-reperfusion injury.

Mechanical effects of heat-moisture exchangers in ventilated patients.

Although they represent a valuable alternative to heated humidifiers, artificial noses have unfavourable mechanical effects. Most important of these is the increase in dead space, with consequent increase in the ventilation requirement. Also, artificial noses increase the inspiratory and expiratory resistance of the apparatus, and may mildly increase intrinsic positive end-expiratory pressure. The significance of these effects depends on the design and function of the artificial nose. The pure humidifying function results in just a moderate increase in dead space and resistance of the apparatus, whereas the combination of a filtering function with the humidifying function may critically increase the volume and the resistance of the artificial nose, especially when a mechanical filter is used. The increase in the inspiratory load of ventilation that is imposed by artificial noses, which is particularly significant for the combined heat-moisture exchanger filters, should be compensated for by an increase either in ventilator output or in patient's work of breathing. Although both approaches can be tolerated by most patients, some exceptions should be considered. The increased pressure and volume that are required to compensate for the artificial nose application increase the risk of barotrauma and volutrauma in those patients who have the most severe alterations in respiratory mechanics. Moreover, those patients who have very limited respiratory reserve may not be able to compensate for the inspiratory work imposed by an artificial nose. When we choose an artificial nose, we should take into account the volume and resistance of the available devices. We should also consider the mechanical effects of the artificial noses when setting mechanical ventilation and when assessing a patient's ability to breathe spontaneously.

Acute effects of inhaled nitric oxide in adult respiratory distress syndrome.

This study evaluated the dose-response effect of inhaled nitric oxide (NO) on gas exchange, haemodynamics, and respiratory mechanics in patients with adult respiratory distress syndrome (ARDS). Of 19 consecutive ARDS patients on mechanical ventilation, eight (42%) responded to a test of 10 parts per million (ppm) NO inhalation with a 25% increase in arterial oxygen tension (Pa,O2,) over the baseline value. The eight NO-responders were extensively studied during administration of seven inhaled NO doses: 0.5, 1, 5, 10, 20, 50 and 100 ppm. Pulmonary pressure and pulmonary vascular resistance exhibited a dose-dependent decrease at NO doses of 0.5-5 ppm, with a plateau at higher doses. At all doses, inhaled NO improved O2 exchange via a reduction in venous admixture. On average, the increase in Pa,O2, was maximal at 5 ppm NO. Some patients, however, exhibited maximal improvement in Pa,O2 at 100 ppm NO. In all patients, the increase in arterial O2 content was maximal at 5 ppm NO. The lack of further increase in arterial O2 content above 5 ppm partly depended on an NO-induced increase in methaemoglobin. Respiratory mechanics were not affected by NO inhalation. In conclusion, NO doses < or =5 ppm are effective for optimal treatment both of hypoxaemia and of pulmonary hypertension in adult respiratory distress syndrome. Although NO doses as high as 100 ppm may further increase arterial oxygen tension, this effect may not lead to an improvement in arterial O2 content, due to the NO-induced increase in methaemoglobin. It is important to consider the effect of NO not only on arterial oxygen tension, but also on arterial O2 content for correct management of inhaled nitric oxide therapy.

Unfavorable mechanical effects of heat and moisture exchangers in ventilated patients.

OBJECTIVE: To investigate the mechanical effects of artificial noses. SETTING: A general intensive care unit of a university hospital. PATIENTS: 10 patients in pressure support ventilation for acute respiratory failure. INTERVENTIONS: The following three conditions were randomly tested on each patient: the use of a heated humidifier (control condition), the use of a heat and moisture exchanger without filtering function (HME), and the use of a combined heat and moisture exchanger and mechanical filter (HMEF). The pressure support level was automatically adapted by means of a closed-loop control in order to obtain constancy, throughout the study, of patient inspiratory effort as evaluated from airway occlusion pressure at 0.1 s (P0.1). Patient's ventilatory pattern, P0.1, work of breathing, and blood gases were recorded. MEASUREMENTS AND MAIN RESULTS: The artificial noses increased different components of the inspiratory load: inspiratory resistance, ventilation requirements (due to increased dead space ventilation), and dynamic intrinsic positive end-expiratory pressure (PEEP). The additional load imposed by the artificial noses was entirely undertaken by the ventilator, being the closed-loop control of P0.1 effective to maintain constancy of patient inspiratory work by means of adequate increases in pressure support level. CONCLUSIONS: The artificial noses cause unfavorable mechanical effects by increasing inspiratory resistance, ventilation requirements, and dynamic intrinsic PEEP. Clinicians should consider these effects when setting mechanical ventilation and when assessing patients' ability to breathe spontaneously.

[Inhaled nitrous oxide (NO) for the treatment of ARDS]. / Ossido nitrico (NO) per via inalatoria nel trattamento dell'ARDS.

OBJECTIVE: To investigate the initial longterm effect of inhaled NO on hypoxemia in ARDS patients. DESIGN: Retrospective study. PATIENTS: Nine hypoxemic patients with ARDS (Murray Lung Injury Score, LIS, 2.8 +/- 0.3), treated with conventional mechanical ventilation. INTERVENTIONS: Continuous NO inhalation was started after a test of inhaled NO efficacy on gas exchange and hemodynamics. Long term effects of inhaled NO were evaluated daily in terms of arterial oxygenation and methemoglobin formation. RESULTS: The initial NO inhalation increased the PaO2/FiO2 from 141 +/- 64 mmHg to 216 +/- 70 mmHg (p < 0.0001) and decreased the mean pulmonary pressure from 38 +/- 7 mmHg to 32 +/- 5 mmHg (p < 0.01), the pulmonary venous admixture from 29 +/- 10% to 20 +/- 8% (p < 0.01) and the pulmonary vascular resistance from 325 +/- 97 dyne.s.cm-5 to 238 +/- 48 dyne.s.cm-5 (p < 0.01). Daily withdrawal of inhaled NO, which was administered for 14 +/- 16 days at 8 +/- 2 ppm, was associated with a decrease in PaO2/FiO2 by 61 +/- 32 mmHg (p < 0.0001). During prolonged NO inhalation the FiO2 was decreased, on average, by 0.34 +/- 0.19 (p < 0.01), the positive end-expiratory pressure by 4 +/- 2 cmH2O (p < 0.01) and the peak inspiratory pressure by 7 +/- 4 cmH2O (p < 0.01). Three patients died during the ICU stay. CONCLUSIONS: Our results confirm the interest for inhaled NO as an additional approach for the treatment of hypoxemia in ARDS. Inhaled NO seems to allow for a better control of gas exchange, rather than for a rapid reduction of the ventilatory support.

Closed-loop control of airway occlusion pressure at 0.1 second (P0.1) applied to pressure-support ventilation: algorithm and application in intubated patients.

OBJECTIVE: Airway occlusion pressure at 0.1 sec (P0.1) is an index of respiratory center output. During pressure-support ventilation, P0.1 correlates with the mechanical output of the inspiratory muscles and has an inverse relationship with the amount of pressure-support ventilation. Based on these observations, we designed a closed-loop control which, by automatically adjusting pressure-support ventilation, stabilizes P0.1, and hence patient inspiratory activity, at a desired target. The purpose of the study was to demonstrate the feasibility of the method, rather than its efficacy or even its influence on patient outcome. DESIGN: Prospective, randomized trial. SETTING: A general intensive care unit of a university hospital in Italy. PATIENTS: Eight stable patients intubated and ventilated with pressure-support ventilation for acute respiratory failure. INTERVENTIONS: Patients were transiently connected to a computer-controlled ventilator on which the algorithm for closed-loop control was implemented. The closed-loop control was based on breath by breath measurement of P0.1, and on comparison with a target set by the user. When actual P0.1 proved to be higher than the target value, the P0.1 controller automatically increased pressure-support ventilation, and decreased it when P0.1 proved to be lower than the target value. For safety, a volume controller was also implemented. Four P0.1 targets (1.5, 2.5, 3.5, and 4.5 cm H2O) were applied at random for 15 mins each. MEASUREMENTS AND MAIN RESULTS: The closed-loop algorithm was able to control P0.1, with a difference from the set targets of 0.59 +/- 0.27 (SD) cm H2O. CONCLUSIONS: The study shows that P0.1 can be automatically controlled by pressure-support ventilation adjustments with a computer. Inspiratory activity can thus be stabilized at a level prescribed by the physician.

Noninvasive evaluation of instantaneous total mechanical activity of the respiratory muscles during pressure support ventilation.

OBJECTIVE: The measurement of esophageal pressure (Pes) is the conventional method for the evaluation of the forces applied to the respiratory system by the respiratory muscles. As an alternative to Pes measurement, we propose the calculation of the instantaneous net pressure applied by the respiratory muscles [Pmusc(t)]. DESIGN: Prospective, randomized study. SETTING: A general ICU of a university hospital. PATIENTS: Eight intubated patients submitted to pressure support ventilation for acute respiratory failure. INTERVENTIONS: Four different levels of pressure support were used to unload progressively the respiratory muscles. Pmusc(t) was calculated at all levels of pressure support and compared with Pes corrected for chest wall load as a reference. Pmusc(t) was further used to calculate inspiratory work of breathing, which in turn was compared with data obtained with the conventional method. MEASUREMENTS AND RESULTS: Airway pressure, airflow, and Pes were measured. Both for amplitude and for timing, Pmusc(t) showed good agreement with reference measurements. Work of breathing as calculated from Pmusc(t) agreed well with the measurement obtained with the conventional method (mean difference, 0.057 +/- 0.157 J). CONCLUSIONS: Noninvasive evaluation of Pmusc(t) allows extended monitoring of mechanical ventilation, which is particularly interesting for pressure preset ventilation modes.