Karl L. Kiening

Bedside microdialysis: a tool to monitor cerebral metabolism in subarachnoid hemorrhage patients?

ObjectiveTo analyze the time course and changes of cerebral microdialysis parameters after aneurysmal subarachnoid hemorrhage (SAH) in respect to the clinical course (asymptomatic, delayed, and acute ischemic neurologic deficits) to evaluate the method of bedside microdialysis in these patients. DesignProspective, controlled study during a 3-yr period. SettingNeurosurgical intensive care unit at a primary level university hospital, supervised and staffed by members of both the department of neurosurgery and the department of anesthesiology and intensive care medicine. PatientsNinety-seven patients (51 females/21 males; 52 ± 13 yrs; World Federation of Neurological Surgeons Scale grades 0–5) after aneurysmatic SAH. Measurements and Main ResultsA microdialysis catheter (CMA 100) was inserted into the region most likely to be affected by vasospasm directly after aneurysm clipping, connected to a pump, and perfused with Ringer solution (0.3 &mgr;L/min). The dialysates were collected hourly and analyzed at the bedside for glucose, lactate, lactate-pyruvate ratio, glutamate, and glycerol (CMA 600). Patients were classified according to clinical presentation as being asymptomatic or having acute (AIND) or delayed (DIND) ischemic neurologic deficits. DIND patients (n = 18) had significantly higher lactate and glutamate concentrations on days 1–8 post-SAH and a higher lactate-pyruvate ratio on days 3–8 post-SAH compared with asymptomatic patients (n = 57;p < .025). Glucose and glycerol levels did not differ in asymptomatic and DIND patients. AIND patients (n = 22) had the worst metabolic pattern: the extracellular glucose concentration was low, whereas the lactate, lactate-pyruvate ratio, glutamate, and glycerol levels were significantly elevated compared with asymptomatic and DIND patients. In 83% of the DIND patients, the changes in metabolites indicative of cerebral ischemia preceded the onset of symptomatic vasospasm. All DIND patients clinically improved in their Glasgow Coma Scale scores with induced hypertension, intentional hypervolemia, and/or hemodilution therapy (p = .01). ConclusionCerebral bedside microdialysis is a safe and promising technique for monitoring (impending) regional cerebral ischemia. The dialysate changes can indicate early the onset of delayed neurologic deterioration and are in good accordance with the clinical course of SAH patients. In the future, this technique may be used to monitor the efficacy of the intensive care therapy of these patients.

Thirty days complication rate following surgery performed for deep-brain-stimulation

Serious adverse events (SAEs) during the first 30 postoperative days after stereotactic surgery for Deep‐Brain‐Stimulation performed in 1,183 patients were retrospectively collected from five German stereotactic centers. The mortality rate was 0.4% and causes for death were pneumonia, pulmonary embolism, hepatopathy, and a case of complicated multiple sclerosis. The permanent surgical morbidity rate was 1%. The most frequently observed SAEs were intracranial hemorrhage (2.2%) and pneumonia (0.6%). Skin infection occurred in 5 of 1,183 patients (0.4%). Surgical complications caused secondary AEs (e.g. pneumonia) preferentially in older patients and in patients treated for Parkinsons disease (PD). Complication rates did not differ among the five centers.

Monitoring of Brain Tissue PO2 in Traumatic Brain Injury: Effect of Cerebral Hypoxia on Outcome

This study investigates the effect of hypoxic brain tissue PO2 on outcome, and examines the incidence of possible causes for cerebral hypoxia. We studied 35 patients with severe head injury (GCS < or = 8). Age was 33.2 (+/- 11.3) years. Total time of monitoring of PtiO2, intracranial pressure (ICP), cerebral perfusion pressure (CPP), and endtidal PCO2 (ETCO2) was 119.3 (+/- 65.7) hours. Data were continuously recorded by a computer system. Outcome was assessed at discharge and after 6 months post injury. 56% of the patients with more than 300 minutes of PtiO2 < 10 mm Hg died, 22% had an unfavourable outcome, 22% had a favourable outcome. Cerebral hypoxia was associated with intracranial hypertension (ICP > 20 mm Hg) in 11.5 (+/- 15.1)%. CPP was compromised below 60 mm Hg in 16.8 (+/- 23.4)%. Hypocarbia (ETCO2 < 28 mm Hg) was present in 48.0% of the time of PtiO2 < 10 mm Hg. No obvious cause for cerebral hypoxia was found in 45% of the data. These result underscore the association of cerebral hypoxia with poor neurological outcome and stress the meaning of monitoring of PtiO2 as an independent parameter in patients following TBI.

Multimodal monitoring in patients with head injury: evaluation of the effects of treatment on cerebral oxygenation.

BACKGROUND Recently, invasive intensive care unit monitoring of cerebral oxygenation has become feasible. The purpose of this study was to investigate the effects of standard therapeutic interventions used in the treatment of intracranial hypertension on cerebral oxygenation and other physiologic parameters in comatose patients. METHODS In the neurosurgical intensive care unit, Ptio2, and jugular bulb oxygen saturation (Sjvo2), arterial blood pressure, intracranial pressure (ICP), and cerebral perfusion pressure (CPP) were prospectively studied (0.1 Hz acquisition rate) with a multimodal monitoring system in 21 patients with severe traumatic brain injury during various treatment modalities: dopamine and mannitol infusion, head positioning, and induced arterial hypocapnia. RESULTS For baseline CPP values below 40 mm Hg, dopamine infusion was more effective in decreasing ICP and improving Ptio2 and Sjvo2 than for initial CPP values above 60 mm Hg. Treatment with mannitol, although improving CPP and lowering ICP, did not affect Ptio2 and Sjvo2. CPP in this group, however, was always above 60 mm Hg. Forced hyperventilation to an end-tidal Pco2 of 21 mm Hg normalized ICP and CPP, but significantly reduced cerebral oxygenation. CONCLUSION A CPP > 60 mm Hg emerges as the crucial factor guaranteeing sufficient brain oxygenation. Any intervention used to further elevate CPP does not improve cerebral oxygenation, to the contrary, forced hyperventilation even bears the risk of inducing brain ischemia.

Pallidal neurostimulation in patients with medication-refractory cervical dystonia: a randomised, sham-controlled trial

BACKGROUND Cervical dystonia is managed mainly by repeated botulinum toxin injections. We aimed to establish whether pallidal neurostimulation could improve symptoms in patients not adequately responding to chemodenervation or oral drug treatment. METHODS In this randomised, sham-controlled trial, we recruited patients with cervical dystonia from centres in Germany, Norway, and Austria. Eligible patients (ie, those aged 18-75 years, disease duration ≥3 years, Toronto Western Spasmodic Torticollis Rating Scale [TWSTRS] severity score ≥15 points) were randomly assigned (1:1) to receive active neurostimulation (frequency 180 Hz; pulse width 120 μs; amplitude 0·5 V below adverse event threshold) or sham stimulation (amplitude 0 V) by computer-generated randomisation lists with randomly permuted block lengths stratified by centre. All patients, masked to treatment assignment, were implanted with a deep brain stimulation device and received their assigned treatment for 3 months. Neurostimulation was activated in the sham group at 3 months and outcomes were reassessed in all patients after 6 months of active treatment. Treating physicians were not masked. The primary endpoint was the change in the TWSTRS severity score from baseline to 3 months, assessed by two masked dystonia experts using standardised videos, analysed by intention to treat. This trial is registered with ClinicalTrials.gov, number NCT00148889. FINDINGS Between Jan 19, 2006, and May 29, 2008, we recruited 62 patients, of whom 32 were randomly assigned to neurostimulation and 30 to sham stimulation. Outcome data were recorded in 60 (97%) patients at 3 months and 56 (90%) patients at 6 months. At 3 months, the reduction in dystonia severity was significantly greater with neurostimulation (-5·1 points [SD 5·1], 95% CI -7·0 to -3·5) than with sham stimulation (-1·3 [2·4], -2·2 to -0·4, p=0·0024; mean between-group difference 3·8 points, 1·8 to 5·8) in the intention-to-treat population. Over the course of the study, 21 adverse events (five serious) were reported in 11 (34%) of 32 patients in the neurostimulation group compared with 20 (11 serious) in nine (30%) of 30 patients in the sham-stimulation group. Serious adverse events were typically related to the implant procedure or the implanted device, and 11 of 16 resolved without sequelae. Dysarthria (in four patients assigned to neurostimulation vs three patients assigned to sham stimulation), involuntary movements (ie, dyskinesia or worsening of dystonia; five vs one), and depression (one vs two) were the most common non-serious adverse events reported during the course of the study. INTERPRETATION Pallidal neurostimulation for 3 months is more effective than sham stimulation at reducing symptoms of cervical dystonia. Extended follow-up is needed to ascertain the magnitude and stability of chronic neurostimulation effects before this treatment can be recommended as routine for patients who are not responding to conventional medical therapy. FUNDING Medtronic.

Decreased hemispheric aquaporin-4 is linked to evolving brain edema following controlled cortical impact injury in rats

The cerebral Aquaporin-4 (AQP4) water channel is suggested to be involved in brain edema formation aggravated by reduced cerebral blood flow early after traumatic brain injury (TBI). Therefore, the temporal profile of brain edema formation, AQP4 expression, and cortical perfusion were investigated following focal TBI in rats. Brain edema was maximal by 24 h. Concurrently, AQP4 protein expression was decreased in both hemispheres, being more pronounced in the traumatized hemisphere (-50%) 48 h after trauma. Cortical perfusion was only decreased in the ipsilateral cortex (-40%) between 4 and 8 h after trauma, reaching baseline values at 24 h. Globally reduced AQP4 expression following induction of a focal contusion coincides with edema development and seems to be independent of changes in cortical perfusion.

Preliminary Evidence That Ketamine Inhibits Spreading Depolarizations in Acute Human Brain Injury

Background and Purpose— Spreading depolarizations, characterized by large propagating, slow potential changes, have been demonstrated with electrocorticography in patients with cerebral hemorrhage and ischemic stroke. Whereas spreading depolarizations are harmless under normal conditions in animals, they cause or augment damage in the ischemic brain. A fraction of spreading depolarizations is abolished by N-methyl-d-aspartate receptor antagonists. Summary of Case— In 2 patients with severe acute brain injury (traumatic and spontaneous intracranial hemorrhage), spreading depolarizations were inhibited by the noncompetitive N-methyl-d-aspartate receptor antagonist ketamine. This restored electrocorticographic activity. Conclusions— These anecdotal electrocorticographic findings suggest that ketamine has an inhibitory effect on spreading depolarizations in humans. This is of potential interest for future neuroprotective trials.

Metabolic changes during impending and manifest cerebral hypoxia in traumatic brain injury

The objective was to measure metabolic changes monitored by bedside microdialysis during impending and manifest hypoxia in traumatic brain injury. In 41 patients, a PtiO2-catheter (Licox; 1/min) was placed into non-lesioned frontal white matter together with a microdialysis catheter (CMA, hourly). Data were analysed for identification of episodes of impending (PtiO2 < 10 - 15 mmHg > 5 min) and manifest cerebral hypoxia (PtiO2 < 10 mmHg, > 5 min). In 69% of patients hypoxic episodes occurred, most frequently associated with hyperventilation (p < 0.001). During impending hypoxia, glutamate was increased (p = 0.03), while the energy metabolites remained stable. Manifest hypoxia was reflected by significant increases of glutamate (p = 0.007) and lactate (p = 0.044), but normal lactate-pyruvate ratios. We conclude that hyperventilation had a potential adverse effect on cerebral metabolism and was most frequently associated with cerebral hypoxia. A PtiO2 < 10 mmHg can induce metabolic changes with increase of glutamate and lactate. The presence of anaerobic cerebral metabolism probably depends on duration and severity of the hypoxic episode.

Balance and motor speech impairment in essential tremor

The pathogenesis of essential tremor (ET) is still under debate. Several lines of evidence indicate that ET is associated with cerebellar dysfunction. The aim of the present study was to find corroborating evidence for this claim by investigating balance and speech impairments in patients with ET. In addition, the effect of deep brain stimulation (DBS) on balance and speech function was studied. A group of 25 ET patients including 18 with postural and/or simple kinetic tremor (ETpt) and seven ET patients with additional clinical signs of cerebellar dysfunction (ETc) was compared to 25 healthy controls. In addition, 12 ET patients with thalamic DBS participated in the study. Balance control was assessed during gait and stance including tandem gait performed on a treadmill as well as static and dynamic posturography. Motor speech control was analyzed through syllable repetition tasks. Signs of balance impairment were found in early stages and advanced stages of ET. During locomotion, ET patients exhibited an increased number of missteps and shortened stride length with tandem gait. ETc patients and, to a lesser extent, ETpt patients had increased postural instability in dynamic posturography conditions that are sensitive to vestibular or vestibulocerebellar dysfunction. ETc but not ETpt patients exhibited significantly increased syllable durations. DBS had no discernable effect on speech performance or balance control. We conclude that the deficits in balance as well as the subclinical signs of dysarthria in a subset of patients confirm and extend previous findings that ET is associated with an impairment of the cerebellum.

Influence of Hyperventilation on Brain Tissue-PO2, PCO2, and pH in Patients with Intracranial Hypertension

A harmful effect of prolonged hyperventilation on outcome has been shown in comatose patients after severe head injury. The purpose of this study was to assess the acute effect of moderate hyperventilation for treatment of intracranial hypertension (ICP < 20 mmHg) on invasively measured brain tissue-PO2 (PtiO2), PCO2 (PtiCO2) and pH (tipH) in severely head injured patients. 15 severely head injured patients (GCS < or = 8) were prospectively studied. Intracranial pressure (ICP), mean arterial blood pressure (MABP), cerebral perfusion pressure (CPP), endtidal CO2 (ETCO2), PtiO2, PtiCO2 and tipH (Paratrend or Licox microsensors) were continuously recorded using multimodal monitoring. Following a baseline period of 15 minutes, patients were hyperventilated for 10 minutes. Arterial blood gas analysis was done before, during and after hyperventilation. At least three hyperventilation maneuvers were performed per patient. For statistical analysis the Friedman test was used. Hyperventilation (paCO2: 32.4 +/- 0.6 to 27.7 +/- 0.5 mmHg) significantly reduced ICP from 25.3 +/- 1.5 to 14.2 +/- 1.9 mmHg (p < 0.01). As a consequence, CPP increased by 9.6 +/- 3.4 mmHg to 76.8 +/- 3.2 mmHg. Brain tissue PCO2 decreased from 37.5 +/- 1.3 to 34.6 +/- 1.2 while tipH increased from 7.13 to 7.16. In all patients, hyperventilation led to a reduction of brain tissue PO2 (PtiO2/Licox: 24.6 +/- 1.4 to 21.9 +/- 1.7 mmHg, n.s.; PtiO2/Paratrend: 35.8 +/- 4.3 to 31.9 +/- 4.0 mmHg, n.s.). In one case hyperventilation even had to be stopped after 7 min because the drop in brain tissue PO2 below 10 mmHg signalized imminent hypoxia. As well known, hyperventilation improves CPP due to a reduction in ICP. However, this does not ameliorate cerebral oxygenation as demonstrated by the decrease in PtiO2. This underlines that hyperventilation should only be used with caution in the treatment of intracranial hypertension.