Neurofilament light increases over time in severe COVID-19 and is associated with delirium.

Neurological monitoring in sedated Intensive Care Unit patients is constrained by the lack of reliable blood-based biomarkers. Neurofilament light is a cross-disease biomarker for neuronal damage with potential clinical applicability for monitoring Intensive Care Unit patients. We studied the trajectory of neurofilament light over a month in Intensive Care Unit patients diagnosed with severe COVID-19 and explored its relation to clinical outcomes and pathophysiological predictors. Data were collected over a month in 31 Intensive Care Unit patients (166 plasma samples) diagnosed with severe COVID-19 at Amsterdam University Medical Centre, and in the first week after emergency department admission in 297 patients with COVID-19 (635 plasma samples) admitted to Massachusetts General hospital. We observed that Neurofilament light increased in a non-linear fashion in the first month of Intensive Care Unit admission and increases faster in the first week of Intensive Care Unit admission when compared with mild-moderate COVID-19 cases. We observed that baseline Neurofilament light did not predict mortality when corrected for age and renal function. Peak neurofilament light levels were associated with a longer duration of delirium after extubation in Intensive Care Unit patients. Disease severity, as measured by the sequential organ failure score, was associated to higher neurofilament light values, and tumour necrosis factor alpha levels at baseline were associated with higher levels of neurofilament light at baseline and a faster increase during admission. These data illustrate the dynamics of Neurofilament light in a critical care setting and show associations to delirium, disease severity and markers for inflammation. Our study contributes to determine the clinical utility and interpretation of neurofilament light levels in Intensive Care Unit patients.

Plasma NfL trajectory during ICU-treatment of COVID-19 patients: A prospective cohort study

Background COVID-19 is a respiratory disease where neurological sequelae are frequently reported. Neurofilament light (NfL) in plasma is a validated biomarker for neuronal damage. We assessed the trajectory of NfL levels in intensive care unit (ICU) patients diagnosed with COVID-19, and studied its relationship to clinical outcomes and markers of hypothesized pathophysiological mechanisms. Method As part of the Art-Deco study and Amsterdam UMC COVID-biobank, longitudinal samples and clinical data were collected weekly from a cohort of 31 prospectively admitted ICU patients with a minimum of 7 days of ventilation. The mean±sd age was 63±11 years. Admission duration ranged from 14-35 days and 156 samples were collected. We evaluated the NfL trajectory over time, and whether this trajectory differed by 90-day mortality outcome. Due to the non-linear trajectory of NfL, we applied linear mixed models including cubic splines for the time variable. Secondly, we tested whether baseline or peak NfL levels predicted mortality (n=7/31), delirium incidence after detubation (n=18/22), and duration of delirium (6±6 days). Third, we assessed if disease severity (day 7 Sequential Organ Failure Assessment [SOFA] score) and baseline hypoxemia (pAO2 before intubation), inflammation (IL1-b, IL-6, IL-8, TNF-α), and coagulopathy (d-dimer, presence of pulmonary embolism) were predictive of the NfL trajectory. For the latter models, we included an interaction term for the pathophysiological markers in the linear mixed models. All models were adjusted for age. Result NfL increased during ICU admission (p<001), and persisted longer in the non-survivors (p<0.05;Figure 1). Baseline or maximum NfL was not predictive of mortality or delirium incidence. However, maximum NfL correlated to the duration of delirium (r=0.5;p=0.02). From the pathophysiological markers, SOFA scores (p<0.05) and baseline TNF-α (p<0.05) were related to a stronger increase of NfL over time. Conclusion NfL levels increased over time and plateaued after 2-3 weeks in most COVID-19 patients at the ICU. Peak levels of NfL were predictive of delirium persistence. Repeated NfL levels may provide a future method for monitoring neurological outcomes in sedated ICU patients. Disease severity and specific inflammatory components appear important predictors of the NfL trajectory reflecting axonal damage in severe COVID-19 patients.

Pulmonary Procoagulant and Innate Immune Responses in Critically Ill COVID-19 Patients.

Rationale: Systemic activation of procoagulant and inflammatory mechanisms has been implicated in the pathogenesis of COVID-19. Knowledge of activation of these host response pathways in the lung compartment of COVID-19 patients is limited. Objectives: To evaluate local and systemic activation of coagulation and interconnected inflammatory responses in critically ill COVID-19 patients with persistent acute respiratory distress syndrome. Methods: Paired bronchoalveolar lavage fluid and plasma samples were obtained from 17 patients with COVID-19 related persistent acute respiratory distress syndrome (mechanical ventilation > 7 days) 1 and 2 weeks after start mechanical ventilation and compared with 8 healthy controls. Thirty-four host response biomarkers stratified into five functional domains (coagulation, complement system, cytokines, chemokines and growth factors) were measured. Measurements and Main Results: In all patients, all functional domains were activated, especially in the bronchoalveolar compartment, with significantly increased levels of D-dimers, thrombin-antithrombin complexes, soluble tissue factor, C1-inhibitor antigen and activity levels, tissue type plasminogen activator, plasminogen activator inhibitor type I, soluble CD40 ligand and soluble P-selectin (coagulation), next to activation of C3bc and C4bc (complement) and multiple interrelated cytokines, chemokines and growth factors. In 10 patients in whom follow-up samples were obtained between 3 and 4 weeks after start mechanical ventilation many bronchoalveolar and plasma host response biomarkers had declined. Conclusions: Critically ill, ventilated patients with COVID-19 show strong responses relating to coagulation, the complement system, cytokines, chemokines and growth factors in the bronchoalveolar compartment. These results suggest a local pulmonary rather than a systemic procoagulant and inflammatory "storm" in severe COVID-19.

Distinct cellular immune profiles in the airways and blood of critically ill patients with COVID-19.

BACKGROUND: Knowledge of the pathophysiology of COVID-19 is almost exclusively derived from studies that examined the immune response in blood. We here aimed to analyse the pulmonary immune response during severe COVID-19 and to compare this with blood responses. METHODS: This was an observational study in patients with COVID-19 admitted to the intensive care unit (ICU). Mononuclear cells were purified from bronchoalveolar lavage fluid (BALF) and blood, and analysed by spectral flow cytometry; inflammatory mediators were measured in BALF and plasma. FINDINGS: Paired blood and BALF samples were obtained from 17 patients, four of whom died in the ICU. Macrophages and T cells were the most abundant cells in BALF, with a high percentage of T cells expressing the ƴδ T cell receptor. In the lungs, both CD4 and CD8 T cells were predominantly effector memory cells (87·3% and 83·8%, respectively), and these cells expressed higher levels of the exhaustion marker programmad death-1 than in peripheral blood. Prolonged ICU stay (>14 days) was associated with a reduced proportion of activated T cells in peripheral blood and even more so in BALF. T cell activation in blood, but not in BALF, was higher in fatal COVID-19 cases. Increased levels of inflammatory mediators were more pronounced in BALF than in plasma. INTERPRETATION: The bronchoalveolar immune response in COVID-19 has a unique local profile that strongly differs from the immune profile in peripheral blood. Fully elucidating COVID-19 pathophysiology will require investigation of the pulmonary immune response.