Advanced neuromonitoring techniques for medical and neurological ICU patients.

Compliance with hand hygiene on surgical, medical, and neurologic intensive care units: Direct observation versus calculated disinfectant usage

Many patients in the intensive care unit (ICU) have predictable medical and discharge outcomes, but some trajectories are marked with medical uncertainty. Stressed family-surrogates receive multiple medical updates from a variety of personnel. These circumstances can lead to confusion, which may result in conflicts and dissatisfaction with care. This study examined the effects of adding a family support coordinator to the surgical, neurological, and medical ICUs on family, physician, and nurse satisfaction with communication and care. A quasi-experimental design was conducted in 2 sequential phases (baseline and intervention). The data sources were 2 surveys: (1) Family Satisfaction Survey and (2) Nurse and Physician Perception and Satisfaction Survey. Family Satisfaction Survey data, a combined data set, were collected in the 3 ICUs. Nurse and Physician Perception and Satisfaction Survey data were collected from the attending physicians and critical care nurses in the medical and neurological ICUs. Results show that family ratings of satisfaction with ICU team communication and care generally increased as a result of the intervention. Overall, physician and nurse perceptions of communication and care did not change as a result of the intervention.

Neurological complications are common in general medical and surgical intensive care units (ICU); they can prolong ICU and hospital stay and worsen outcome, including mortality. We performed a descriptive analysis of neurological consultations in non-neurological ICUs to determine the frequency of various neurological complications and to assess the diagnostic yield, therapeutic implications and prognostic benefit of these consultations. This is a retrospective single group cohort study of all neurological consultations for patients admitted to non-neurological (medical, respiratory care unit, cardiac, cardiothoracic, surgical and trauma) ICUs at Saint Marys Hospital (Mayo Clinic, Rochester) over a 24-month period (01 January 2010 to 31 December 2011). Equal numbers of neurological consultations (174, 50% each) were requested from medical ICUs and surgical ICUs. Altered consciousness (158, 45%), seizure (76, 22%) and focal deficits (75, 22%) were the most common reasons for consultations. Diagnostic, prognostic and therapeutic benefit was considered present in 89%, 38% and 39% patients respectively. Treatment change following neurological consultation occurred in 48% patients. Encephalopathy, stroke, seizure and anoxic brain injury were the most common causes of neurological complications in non-neurological ICUs with sedatives and opiates being the most common cause of encephalopathy. Almost half of the patients had change in treatment following neurological consultation. Neurological consultations in non-neurological ICU's are beneficial for patient's care in terms of diagnosis, treatment and prognosis.

Cerebral function monitors during pediatric cardiac surgery: Can they make a difference?

Foreword

To explore the basic characteristics of various types of intensive care unit (ICU) patients and the predictive value of six common disease severity scores in critically ill patients on the first day on the 28-day death risk. The general information, disease severity scores [acute physiology score III (APS III), Oxford acute disease severity (OASIS) score, Logistic organ dysfunction score (LODS), simplified acute physiology score II (SAPS II), systemic inflammatory response syndrome (SIRS) score and sequential organ failure assessment (SOFA) score], prognosis and other indicators of critically ill patients admitted from 2008 to 2019 were extracted from Medical Information Mart for Intensive Care-IV 2.0 (MIMIC-IV 2.0). The receiver operator characteristic curve (ROC curve) of six critical illness scores for 28-day death risk of patients in various ICU, and the area under the ROC curve (AUC) was calculated, the optimal Youden index was used to determine the cut-off value, and the AUC of various ICU was verified by Delong method. A total of 53 150 critically ill patients were enrolled, with medical ICU (MICU) accounted for the most (19.25%, n = 10 233), followed by cardiac vascular ICU (CVICU) with 17.78%(n = 9 450), and neurological ICU (NICU) accounted for the least (6.25%, n = 3 320). The patients in coronary care unit (CCU) were the oldest [years old: 71.79 (60.27, 82.33)]. The length of ICU stay in NICU was the longest [days: 2.84 (1.51, 5.49)] and accounted for the highest proportion of total length of hospital stay [63.51% (34.61%, 97.07%)]. The patients in comprehensive ICU had the shortest length of ICU stay [days: 1.75 (0.99, 3.05)]. The patients in CVICU had the lowest proportion of length of ICU stay to total length of hospital stay [27.69% (18.68%, 45.18%)]. The six scores within the first day of ICU admission in NICU patients were lower than those in the other ICU, while APS III, LODS, OASIS, and SOFA scores in MICU patients were higher than those in the other ICU. SAP II and SIRS scores were both the highest in CVICU, respectively. In terms of prognosis, MICU patients had the highest 28-day mortality (14.14%, 1 447/10 233), while CVICU patients had the lowest (2.88%, 272/9 450). ROC curve analysis of the predictive value of each score on the 28-day death risk of various ICU patients showed that, the predictive value of APS III, LODS, and SAPS II in comprehensive ICU were higher [AUC and 95% confidence interval (95%CI) were 0.84 (0.83-0.85), 0.82 (0.81-0.84), and 0.83 (0.82-0.84), respectively]. The predictive value of OASIS, LODS, and SAPS II in surgical ICU (SICU) were higher [AUC and 95%CI were 0.80 (0.79-0.82), 0.79 (0.78-0.81), and 0.79 (0.77-0.80), respectively]. The predictive value of APS III and SAPS II in MICU were higher [AUC and 95%CI were 0.84 (0.82-0.85) and 0.82 (0.81-0.83), respectively]. The predictive value of APS III and SAPS II in CCU were higher [AUC and 95%CI were 0.86 (0.85-0.88) and 0.85 (0.83-0.86), respectively]. The predictive value of LODS and SAPS II in trauma ICU (TICU) were higher [AUC and 95%CI were 0.83 (0.82-0.83) and 0.83 (0.82-0.84), respectively]. The predictive value of OASIS and SAPS II in NICU were higher [AUC and 95%CI were 0.83 (0.80-0.85) and 0.81 (0.78-0.83), respectively]. The predictive value of APS III, LODS, and SAPS II in CVICU were higher [AUC and 95%CI were 0.84 (0.83-0.85), 0.81 (0.80-0.82), and 0.78 (0.77-0.78), respectively]. For the patients in comprehensive ICU, MICU, CCU, and CVICU, APS III or SAPS II can be applied for predicting 28-day death risk. For the patients in SICU and NICU, OASIS or SAPS II can be applied to predict 28-day death risk. For the patients in TICU, SAPS II or LODS can be applied for predicting 28-day death risk. For CVICU patients, APS III or LODS can be applied to predict 28-day death risk.

Although convulsive seizures occurring during pilocarpine-induced epileptogenesis have received considerable attention, nonconvulsive seizures have not been closely examined, even though they may reflect the earliest signs of epileptogenesis and potentially guide research on antiepileptogenic interventions. The definition of nonconvulsive seizures based on brain electrical activity alone has been controversial. Here we define and quantify electrographic properties of convulsive and nonconvulsive seizures in the context of the acquired epileptogenesis that occurs after pilocarpine-induced status epilepticus (SE). Lithium-pilocarpine was used to induce the prolonged repetitive seizures characteristic of SE; when SE was terminated with paraldehyde, seizures returned during the 2-day period after pilocarpine treatment. A distinct latent period ranging from several days to >2 wk was then measured with continuous, long-term video-EEG. Nonconvulsive seizures dominated the onset of epileptogenesis and consistently preceded the first convulsive seizures but were still present later. Convulsive and nonconvulsive seizures had similar durations. Postictal depression (background suppression of the EEG) lasted for >100 s after both convulsive and nonconvulsive seizures. Principal component analysis was used to quantify the spectral evolution of electrical activity that characterized both types of spontaneous recurrent seizures. These studies demonstrate that spontaneous nonconvulsive seizures have electrographic properties similar to convulsive seizures and confirm that nonconvulsive seizures link the latent period and the onset of convulsive seizures during post-SE epileptogenesis in an animal model. Nonconvulsive seizures may also reflect the earliest signs of epileptogenesis in human acquired epilepsy, when intervention could be most effective. NEW & NOTEWORTHY Nonconvulsive seizures usually represent the first bona fide seizure following a latent period, dominate the early stages of epileptogenesis, and change in severity in a manner consistent with the progressive nature of epileptogenesis. This analysis demonstrates that nonconvulsive and convulsive seizures have different behavioral outcomes but similar electrographic signatures. Alternatively, epileptiform spike-wave discharges fail to recapitulate several key seizure features and represent a category of electrical activity separate from nonconvulsive seizures in this model.

Nonconvulsive Electrographic Seizures after Traumatic Brain Injury Result in a Delayed, Prolonged Increase in Intracranial Pressure and Metabolic Crisis. Vespa PM, Miller C, McArthur D, Eliseo M, Etchepare M, Hirt D, Glenn TC, Martin N, Hovda D. Crit Care Med 2007; [Epub ahead of print]. OBJECTIVE: To determine whether nonconvulsive electrographic post-traumatic seizures result in increases in intracranial pressure and microdialysis lactate/pyruvate ratio. DESIGN: Prospective monitoring with retrospective data analysis. SETTING: Single center academic neurologic intensive care unit. PATIENTS: Twenty moderate to severe traumatic brain injury patients (Glasgow Coma Score 3–13). MEASUREMENTS AND MAIN RESULTS: Continuous electroencephalography and cerebral microdialysis were performed for 7 days after injury. Ten patients had seizures and were compared with a matched cohort of traumatic brain injury patients without seizures. The seizures were repetitive and constituted status epilepticus in seven of ten patients. Using a within-subject design, post-traumatic seizures resulted in episodic increases in intracranial pressure (22.4 ± 7 vs. 12.8 ± 4.3 mm Hg; p < .001) and an episodic increase in lactate/pyruvate ratio (49.4 ± 16 vs. 23.8 ± 7.6; p < .001) in the seizure group. Using a between-subjects comparison, the seizure group demonstrated a higher mean intracranial pressure (17.6 ± 6.5 vs. 12.2 ± 4.2 mm Hg; p < .001), a higher mean lactate/pyruvate ratio (38.6 ± 18 vs. 27 ± 9; p < .001) compared with nonseizure patients. The intracranial pressure and lactate/pyruvate ratio remained elevated beyond postinjury hour 100 in the seizure group but not the nonseizure group (p < .02). CONCLUSION: Post-traumatic seizures result in episodic as well as long-lasting increases in intracranial pressure and microdialysis lactate/pyruvate ratio. These data suggest that post-traumatic seizures represent a therapeutic target for patients with traumatic brain injury.

Background: Intracranial pressure (ICP) monitoring and cerebral perfusion pressure (CPP) monitoring are long established adjuncts in the management of traumatic brain injuries (TBIs). However, brain tissue oxygenation (PbtO2) monitoring, used in conjunction with ICP or CPP monitoring, is an additional element that could be used in directing the management of TBIs. Aims: To determine the impact of PbtO2 monitoring on mortality in adult patients with severe TBIs. Methods: A systematic review of electronic databases was performed in October 2021. A total of six articles were identified for inclusion. Data were extracted using a pre-designed extraction tool. Analysis was undertaken using RevMan for the mortality rates and a narrative analysis for the secondary outcomes. Findings: A total of 926 participants were evaluated. Of these, 269 received PbtO2 monitoring. There was no significant difference in mortality rates between the groups, with the PbtO2 and ICP/CPP groups having a mortality rate of 25% (72/284) and 26% (171/662), respectively. The odds ratio was calculated as 0.88 (0.63–1.23, P=0.45) suggesting a 37% reduction in the odds of mortality when PbtO2 is used. However, the 95% confidence intervals do indicate a non-statistical finding. Morbidity rates between the two groups were also similar, with some limited evidence (one study) demonstrating a higher fiscal cost associated with PbtO2 monitoring. Conclusions: There was no significant difference in mortality or morbidity rates between the two groups. Based on these results, this systematic review cannot support the addition of PbtO2 monitoring to guide the treatment of adult patients with severe TBIs.

An Update on Neurocritical Care for the Patient With Kidney Disease

Neurologic critical care encompasses the management of many nervous system diseases when they present in the extremes of severity. Core conditions managed in the neuroscience intensive care unit (ICU) include stroke, cerebral hemorrhage, status epilepticus (SE), myasthenia gravis (MG), Guillain-Barré syndrome (GBS), traumatic brain and spinal cord injury, and high-risk postoperative neurosurgical patients. The skills and knowledge base required to care for patients with such conditions, and the life-threatening complications associated with them, are drawn from both traditional neurology and from critical care medicine. This chapter covers specialized monitoring in the neurologic intensive care unit and special conditions such as acute intracranial hypertension, acute ischemic stroke, intracerebral hemorrhage, venous sinus thrombosis, myasthenia gravis, GBS, seizure and status epilepticus, spinal cord injury, and traumatic brain injury. The chapter includes 8 tables and 5 figures. Tables provide common etiologies of acute intracranial hypertension; general prophylactic measures, medical interventions, surgical interventions, and stepwise treatment protocol for acute intracranial hypertension; drugs that can exacerbate weakness in myasthenia gravis, cholinergic drug dosage equivalents and duration of action, and antiseizure medications used in status epilepticus. Figures illustrate the Monro-Kellie Doctrine, intracranial pressure waveform and plateau waves, typical herniation patterns, large stroke with malignant edema, and examples of nontraumatic intracerebral hemorrhage. This chapter contains 114 references.

Ventilator-associated pneumonia (VAP) is a preventable secondary consequence of intubation and mechanical ventilation. VAP is pneumonia that develops in an intubated patient after 48 hours or more of mechanical ventilator support. Mechanically ventilated patients in neurologic and other intensive care units (ICUs) are at an increased risk of VAP due to factors such as decreased level of consciousness; dry, open mouth; and microaspiration of secretions. VAP can be prevented by initiating interventions from the Institute of Healthcare Improvement's VAP bundle, including (a) elevating the head of the bed of ventilated patients to 30 degrees, (b) preventing venous thromboembolism through use of sequential compression devices or anticoagulation, (c) administering gastric acid histamine2 blockers, (d) practicing good hand hygiene, (e) initiating early mobilization, and (f) performing daily sedation interruption at 10 am to evaluate neurologic status. The one intervention not included in the IHI bundle is oral hygiene. The purpose of this project is to support the premise that oral care, including timed toothbrushing, combined with the VAP bundle can mitigate and prevent the occurrence of VAP. Our project specifically addressed timed oral care of mechanically ventilated patients on a 24-bed stroke, neurologic, and medical ICU. Patients were randomized into a control group that performed usual oral care or an intervention group that brushed teeth every 8 hours. The results were immediate and startling, as the VAP rate dropped to zero within a week of beginning the every-8-hours toothbrushing regimen in the intervention group. The study was so successful that the control group was dropped after 6 months, and all intubated patients' teeth were brushed every 8 hours, maintaining the zero rate until the end of the study.

The early pathophysiological features of traumatic brain injury observed in the intensive care unit (ICU) have been described in terms of altered cerebral blood flow, altered brain metabolism, and neurochemical excitotoxicity. Seizures occur in animal models of brain injury and in human brain injury. Previous studies of posttraumatic seizures in humans have been based principally on clinical observations without a systematic approach to electroencephalographic (EEG) recording of seizures. The purpose of this study was to determine prospectively the incidence of convulsive and nonconvulsive seizures by using continuous EEG monitoring in patients in the ICU during the initial 14 days post-injury. Ninety-four patients with moderate-to-severe brain injuries underwent continuous EEG monitoring begin-ning at admission to the ICU (mean delay 9.6+/-5.4 hours) and extending up to 14 days postinjury. Convulsive and nonconvulsive seizures occurred in 21 (22%) of the 94 patients, with six of them displaying status epilepticus. In more than half of the patients (52%) the seizures were nonconvulsive and were diagnosed on the basis of EEG studies alone. All six patients with status epilepticus died, compared with a mortality rate of 24% (18 of 73) in the nonseizure group (p<0.001). The patients with status epilepticus had a shorter mean length of stay (9.14+/-5.9 days compared with 14+/-9 days [t-test, p<0.031). Seizures occurred despite initiation of prophylactic phenytoin on admission to the emergency room, with maintenance at mean levels of 16.6+/-2.8 mg/dl. No differences in key prognostic factors (such as the Glasgow Coma Scale score, early hypoxemia, early hypotension, or 1-month Glasgow Outcome Scale score) were found between the patients with seizures and those without. Seizures occur in more than one in five patients during the 1st week after moderate-to-severe brain injury and may play a role in the pathobiological conditions associated with brain injury.

Object The early pathophysiological features of traumatic brain injury observed in the intensive care unit (ICU) have been described in terms of altered cerebral blood flow, altered brain metabolism, and neurochemical excitotoxicity. Seizures occur in animal models of brain injury and in human brain injury. Previous studies of posttraumatic seizures in humans have been based principally on clinical observations without a systematic approach to electroencephalographic (EEG) recording of seizures. The purpose of this study was to determine prospectively the incidence of convulsive and nonconvulsive seizures by using continuous EEG monitoring in patients in the ICU during the initial 14 days postinjury. Methods Ninety-four patients with moderate-to-severe brain injuries underwent continuous EEG monitoring beginning at admission to the ICU (mean delay 9.6 ± 5.4 hours) and extending up to 14 days postinjury. Convulsive and nonconvulsive seizures occurred in 21 (22%) of the 94 patients, with six of them displaying status epilepticus. In more than half of the patients (52%) the seizures were nonconvulsive and were diagnosed on the basis of EEG studies alone. All six patients with status epilepticus died, compared with a mortality rate of 18 (24%) of 73 in the nonseizure group (p &lt; 0.001). The patients with status epilepticus had a shorter mean length of stay (9.14 ± 5.9 days compared with 14 ± 9 days (t-test, p &lt; 0.03). Seizures occurred despite initiation of prophylactic phenytoin on admission to the emergency room, with maintenance at mean levels of 16.6 ± 2.8 mg/dl. No differences in key prognostic factors (such as the Glasgow Coma Scale score, early hypoxemia, early hypotension, or 1-month Glasgow Outcome Scale score) were found between the patients with seizures and those without. Conclusions Seizures occur in more than one in five patients during the 1st week after moderate-to-severe brain injury and may play a role in the pathobiological conditions associated with brain injury.

Certain admission characteristics are known predictors of adverse outcomes in patients with moderatesevere TBI, but explain only 1/3 of outcome variability. Intensive care unit (ICU) complications occur frequently in this population, but their impact on patient outcomes remains poorly defined. In a prospective observational cohort study of 170 consecutive moderate-severe TBI patients admitted to Level I trauma center (UMASS) over the period 11/2009–2/2012, we examined the association of ICU complications and 3-month outcome (Glasgow Outcome Scale [GOS]). The mean age was 51 years, 72% were men, and the median GCS and injury severity scores were 4 and 29, respectively. Using multiple logistic regression analysis, hypotension requiring vasopressors (HRV) was the strongest predictor of poor outcome (GOS 1-3 [OR 2.8; 95% CI 1-7.5]) among medical complications. After combining medical with neurological ICU complications, brain herniation (OR 5.8; 95% CI 1.1-30.2) and intracranial rebleeding (OR 2.9; 95% CI 1-8.4) were the strongest predictors of poor outcome, while HRV approached significance (OR 2.4; 95% CI 0.9-6.4). We identified important potentially modifiable predictors of adverse outcomes after moderate-severe TBI. Confirmation of our findings in a larger cohort is warranted.