Lack of correlation among intracerebral cytokines, intracranial pressure, and brain tissue oxygenation in patients with traumatic brain injury and diffuse lesions.

OBJECTIVES: To determine the evolution of cytokine patterns using microdialysis in patients with traumatic brain injury with diffuse lesions and to study the relationship between cytokines and intracranial pressure, brain tissue oxygenation and lesion type on the computed cranial tomography scan (patients with and without brain swelling). DESIGN: Prospective and observational study. SETTING: Third-level university hospital. PATIENTS: Patients between 15 and 65 yrs with severe traumatic brain injury and a diffuse lesion requiring intracranial pressure and brain tissue oxygenation monitoring were eligible. INTERVENTIONS: Microdialysis catheters with a high-cutoff membrane of 100 kDa were inserted. RESULTS: Sixteen patients were included in the analysis. There was a substantial interindividual variability between cytokine values. The highest concentrations for the interleukin-1ß, interleukin-6, and interleukin-8 were measured during the first 24 hrs followed by a gradual decline. The average concentration for interleukin-10 did not vary over time. This pattern is the most frequent in patients with traumatic brain injury with diffuse lesions. The intracranial pressure-cytokines correlation coefficients for the 16 patients varied substantially: interleukin-1ß-intracranial pressure (-0.76 to 0.63); interleukin-6-intracranial pressure (-0.83 to 0.78); interleukin-8-intracranial pressure (-0.86 to 0.84); and interleukin-10-intracranial pressure (-0.36 to 0.65). The brain tissue oxygenation-cytokine correlation coefficients, like with intracranial pressure, also varied between patients: interleukin-1ß-brain tissue oxygenation (-0.49 to 0.68), interleukin-6-brain tissue oxygenation (-0.99 to 0.84); interleukin-8-brain tissue oxygenation (-0.65 to 0.74); and interleukin-10-brain tissue oxygenation (-0.34 to 0.52). Similarly, we found no difference in the cytokine values inpatient microdialysis with and without swelling in the computed tomographic scan. CONCLUSIONS: No clear relationship was found between the temporal pattern of cytokines and the behavior of the intracranial pressure, brain tissue oxygenation, and the presence or absence of swelling in the computed tomography scan. This study demonstrates the feasibility of microdialysis in recovering cytokines for a prolonged time, although there may be some nonresolved methodologic problems with this technique when we try to study the inflammation during traumatic brain injury that could affect the results and make interpretation of microdialysis data prone to difficulties.

Loss of cortisol circadian rhythm in patients with traumatic brain injury: a microdialysis evaluation.

BACKGROUND: Traumatic brain injury (TBI) is commonly associated with disturbances of the hypothalamic-pituitary-adrenal axis secretion. Cerebral microdialysis techniques have been recently applied to measure brain interstitial cortisol levels. METHODS: We evaluated for the first time the circadian rhythm of cortisol secretion at 08:00, 16:00, and 24:00 h in the acute phase of TBI by determination of total serum and brain interstitial cortisol levels (microdialysis samples) in 10 patients with TBI. Non-parametric Friedman's two way analysis of variance test was used. RESULTS: Mean age was 29.8 ± 13.6 years. Median Glasgow Coma Scale score after resuscitation was 5 (range 3-10). No differences were found in total serum (P = 0.26) and brain interstitial cortisol (P = 0.77) in the whole sample. Intraindividual analysis showed that circadian variability was lost in all patients, both in serum and brain interstitial cortisol samples in the acute phase after TBI. CONCLUSION: In our series, circadian variability of cortisol evaluated by serum and cerebral microdialysis samples seems to be lost in TBI patients.

[Study of a brain microcirculation in cranioencephalic trauma using the Side Stream Field (SDF) system]. / Estudio de la microcirculación cerebral en el traumatismo craneoencefálico mediante el sistema Side Stream Dark Field (SDF).

Posttraumatic tissular hypoxia can be due to multiple causes, including microcirculation disturbances, which can be studied with the SDF (Side Stream Dark Field) system. This system is based on a small hand-held microscope that eliminates directly reflected green polarised light from an organ surface using an orthogonal analyser. It offers clear images of red and white blood cells flow through microcirculation. Specific software is later used to determine the length and density of microvessels. We present a case of a TBI patient who required surgical evacuation of a brain contusion. Images of the microcirculatory bed were recorded with the SDF microscope and compared with a normal pattern obtained from another patient who was operated on for an unruptured cerebral aneurysm. Both imaging and quantitative analyses showed significant differences in the cerebral microcirculatory status in these patients. Total length and density of vessels were markedly reduced in the TBI patient. SDF imaging allows direct and non-invasive in vivo observation of cerebral microcirculation, and may allow us to deepen our knowledge of the pathophysiology of posttraumatic brain ischemia.