Brain Iron Metabolism and early brain injury following subarachnoid hemorrhage: iCeFISH-pilot (CSF iron in SAH)

Abstract

Objectives

To explore the relationship between levels of non-protein bound iron in cerebrospinal fluid and the development of early brain injury in patients with aneurysmal SAH.

Design

Prospective observational cohort pilot study.

Setting

Neurointensive care unit of an academic, tertiary medical center

Patients

Patients admitted with aneurysmal subarachnoid hemorrhage Hunt and Hess grades 2 to 4 requiring ventriculostomy insertion as part of their clinical management.

Interventions

None.

Measurements and main results

Samples of cerebrospinal fluid (CSF) were obtained on days 1, 3, and 5. A fluorometric assay that relies on an oxidation sensitive probe was used to measure unbound iron, and levels of iron-handling proteins were measured by means of enzyme-linked immunosorbent assays. We prospectively collected and recorded demographic, clinical, and radiological data. A total of 12 patients were included in this analysis. Median Hunt and Hess score on admission was 3.5 (IQR: 1) and median modified Fisher scale score was 4 (IQR: 1). Seven of 12 patients (58%) developed delayed cerebral ischemia (DCI). Day 5 non-transferrin bound iron (NTBI) (7.88±1 vs. 3.58± 0.8, p= 0.02) and mean NTBI (7.39± 0.4 vs. 3.34±0.4 p= 0.03) were significantly higher in patients who developed DCI. Mean and day 3 levels of redox-active iron correlated with development of angiographic vasospasm in logistic regression analysis (p= 0.02); while mean redox-active iron and lower levels of ceruloplasmin on days 3, 5 and peak were correlated with development of deep cerebral infarcts.

Conclusions

our preliminary data indicate a causal relationship between unbound iron and brain injury following SAH and suggest a possible protective role for ceruloplasmin in this setting, particularly in the prevention of cerebral ischemia. Further studies are needed to validate these findings and to probe their clinical significance.

Introduction

Recent evidence suggests that oxidative injury due to hemoglobin (Hb) and iron overload is a major contributor to neuronal damage following intracerebral hemorrhage (ICH),¹ and an iron-chelating drug is being tested as a potential therapeutic intervention in ICH patients.^2,3 In aneurysmal subarachnoid hemorrhage (SAH), erythrocytes lyse in the subarachnoid space and expose the brain to high concentrations of Hb.⁴ The catabolism of heme, mediated by heme-oxygenase, leads to the release of iron, which easily overwhelms the homeostatic mechanisms normally present in the CNS.⁵

In humans, iron can be found either tightly bound to carrier proteins (i.e. transferrin) or liberated/translocated (also referred to as “free iron”).⁶ The reduction of bound ferric iron from carrier proteins to its “free” ferrous form is likely accomplished by the acidic pH and cathecolamines found in the extracellular fluid following brain injury.⁷ In its reduced (i.e. ferrous) form, iron is free to participate in the Fenton reaction leading to the formation of reactive oxygen species (ROS) and subsequent lipid peroxidation, which have been implicated in the etiology of vasospasm (VSP) and neuronal injury following experimental subarachnoid hemorrhage (SAH).⁸

Non-transferrin bound iron (NTBI) encompasses all forms of the metal that are not tightly associated with transferrin. Redox-active iron (REDOX-Fe) represents the component of NTBI that is both redox-active (ferrous) and chelatable.⁹ No clinical studies have evaluated the role of non-protein bound iron in SAH and iron-mediated neurotoxicity following aneurysm rupture represents a promising therapeutic target that thus far remains unexplored. In this pilot study we set out to examine the changes in REDOX-Fe and NTBI, as well as the concentration of the main iron-handling and regulating proteins in the cerebrospinal fluid (CSF) of patients over the first five days following SAH.

Methods

Subjects

This study was reviewed and approved by the local institutional review board and consent for enrollment was obtained from a next of kin or a legal representative if patients were deemed unfit to provide informed consent. Consecutive eligible patients between the ages of 18 and 80 years admitted to the Cleveland Clinic Neurointensive care unit following aneurysmal SAH were included. Only patients with Hunt and Hess clinical grades between 2 and 4 at presentation, with a clear time of onset of symptoms, and requiring insertion of an external ventricular drain (EVD) were considered for participation in this pilot study. Clinical management was at the discretion of the neurocritical care and neurosurgical teams and consistent with published guidelines and current standards of care.^{10, 11} Demographic and clinical data were prospectively collected and recorded.

Demographic, clinical, and radiographic data

Age, gender, past medical history, baseline and 90-day modified Rankin scale (mRS), admission systolic (SBP) and mean arterial pressure (MAP), core body temperature, Glasgow coma scale (GCS), Hunt and Hess (HHS), modified Fisher scale (mFS), and aneurysm location and size (on its largest axis) were recorded.

Episodes of clinical deterioration secondary to delayed cerebral ischemia (DCI) defined as any focal neurological impairment or GCS reduction ≥ 2 points lasting at least 1 hour and not attributable to any other condition¹² were documented, as was the initiation of hypertensive hypervolemic therapy (HHT) in response to DCI. Duration of EVD, eventual need for ventriculo-peritoneal shunt, ICU and hospital length of stay (LOS) and discharge disposition (acute rehabilitation facility or home vs. other) were recorded. Subsequent outpatient assessment was performed at 90 days from hospital admission.

Functional status was assessed by means of the modified Rankin scale (mRS) by certified investigators during an outpatient visit; for the purpose of the present study an mRS score of 0–2 was considered good functional outcome, while a score of 3 or higher, a poor one. Acute cerebral infarcts (CI) present on diffusion-weighted (DWI) sequences from magnetic resonance imaging (MRI) obtained as part of clinical care were recorded following a previously validated classification that has been shown to correlate with clinical outcomes (Naidech 2009) and that relies on the number and location of positive DWI lesions.¹³ Cerebral angiograms were reviewed by two interventional neurologists for presence of radiographic vasospasm, defined as a reduction of at least 50% in vessel caliber in one or more vascular axis. Investigators recording clinical and radiographic data were blinded to results of CSF analysis.

CSF Samples

Samples were obtained at 24 ± 8h, 72 ± 8h, and 120 ± 8 hours from onset of symptoms. Fluid was obtained from the burette attached to the EVD system, allowing only sampling of CSF drained during the preceding hour. A total of 6 ml were collected at each time point and immediately centrifuged at 2,000 g for 10 minutes. The supernatant was aliquoted in small polypropylene cryovials and stored at −80 °C. Protease inhibitor (Halt, Thermo scientific) was added a priori to the cryovials destined for protein determination.¹⁴

Samples of CSF obtained from four patients who had lumbar drain insertion and fluid drainage to rule out the presence of normal pressure hydrocephalus and that resulted normal and free from pathological alterations after testing analysis were used as controls for the determination of iron and protein concentrations for comparison purposes.

Redox-active iron and non-transferrin bound iron determination

Both REDOX-Fe and NTBI were determined by a modification of protocol previously described for labile plasma iron.¹⁵ Briefly, quadruplicates of 10 μl of CSF were transferred to clear-bottom, 384-well plates (ThermoFisher Scientific, USA). Iron-free HEPES-buffered saline (90 μl; HBS; HEPES 20 nM, NaCl 150 mM, pH 7.4) containing 40 μM ascorbate and 50 μM DHR (dihydrorhodamine 123, di-hydrochloride salt, Sigma-Aldrich, St Louis, MO, USA) was added to two of the wells. Ninety microliters of the same solution containing 50 μM of the iron chelator deferiprone (L1; Sigma-Aldrich, St Louis, MO) was added to the other two wells. Following reagent addition, the kinetics of fluorescence increase were followed at 37 °C in a Spectramax M2e microplate reader (Molecular Devices, Sunnyvale, CA) with a 485/538 nm excitation/emission filter pair, for 40 minutes, with readings every two minutes. The slopes (r) of DHR fluorescence intensity with time were calculated from measurements taken between 15–40 minutes and were recorded as FU/min (fluorescence units per minute). The duplicate values of r in the presence and absence of L1, r_L1 and r, respectively, were averaged and the redox-active CSF iron (REDOX-Fe) concentration was determined from calibration curves relating the difference in slopes with and without L1 against Fe concentration: REDOX-Fe = ∆r/r_st = (r - r_L1)/r_st, where ∆r and r_st denote the L1 sensitive component of r and the calibration factor relating ∆r to the Fe concentration, respectively. Calibration curves were prepared by serial dilutions of Fe:nitriloacetate, (1:7, mol:mol) to give final concentrations of 5, 2.5, 1.25, 0.625, 0.313, 0.156 and 0.078 μM Fe in HBS buffer containing 0.3 mg/ml bovine serum albumin.

For the calculation of NTBI, the process described above was repeated, but nitriloacetic acid (NTA; 0.5 μM; Sigma-Aldrich, St Louis, MO), a weak iron mobilizer was added to the wells prior to the measurement of the kinetics of fluorescence. Cerebrospinal fluid REDOX-Fe and NTBI are expressed in micromolar (μM).

Iron-handling proteins determination

Measurements of ferritin, transferrin, lactoferrin, ceruloplasmin, (Abcam ELISA kits; Cambridge, MA) and pro-hepcidin (MyBiosource, San Diego, CA) in CSF were performed using enzyme-linked immunosorbent assays and the concentrations expressed following the standards set by the International System of Units (SI Units).

Statistical analysis

All values for CSF tests are expressed as mean ± standard error of the mean. Comparison between SAH patients and control subjects and between patients who developed DCI and those who did not was made using the Wilcoxon Rank Sum test (assuming a non-parametric distribution of data) and intergroup comparisons among the 3 groups were determined by 1-way analysis of variance (ANOVA). Student’s T-test was used to compare means of normally distributed data, bivariate analysis and logistic regression to explore relationships between continuous variables and Fisher’s exact test for analysis of categorical datasets. For statistical purposes, the 90-day mRS was dichotomized to ≤ 2 to define favorable functional outcome and > 2 for unfavorable outcome. A p value of < 0.05 was considered statistically significant. All the computations were done using JMP 10.0 and SAS 9.2 (SAS Institute, INC.)

Results

Demographic and clinical data

Fourteen patients with SAH were initially consented, but only 12 are included in the present analysis. One patient was made comfort care status within 24 hours of admission and another had malfunction of the ventriculostomy system that lead to early discontinuation of the EVD system. Table 1 summarizes the demographic and clinical characteristics of our patients overall and by DCI status. The majority of patients were women (83%) with a mean age of 57.5 ± 6.3 years. The prevalence of history of hypertension and smoking was high in this cohort (83%). Four of 12 patients were comatose on admission; the median HHS score at presentation was 3.5 (IQR 1), while the median mFS score on admission was 4 (IQR 1). Most aneurysms were located in the anterior circulation (75%). Eleven patients (92%) underwent aneurysm coiling, while only one patient was treated with craniotomy and clipping.

Table 1.

Demographic and clinical characteristics of SAH patients by delayed cerebral ischemia status. HTN: hypertension, Tob: tobacco, IA: intracranial; aneurysm; mRS: modified Rankin scale; IQR: interquartile range; GCS: Glasgow coma scale; HHS: Hunt and Hess scale; mFS: modified Fisher scale; AC: anterior circulation; SBP: systolic blood pressure; MAP: mean arterial pressure; Hb: hemoglobin; CI: cerebral infarct; HHT: hypertensive, hypervolemic therapy; M. Vent: mechanical ventilation, EF: ejection fraction; EVD: ventriculostomy drain; LOS: length of stay. Data given in mean ± SD, unless otherwise indicated.

	Total (12)	DCI (7)	No DCI (5)	p
Demographics:
-Age (yrs)	57.5 ± 6.3	55.8 ± 3.7	60 ± 8.7	0.3
-Gender: female (%)	10 (83)	5 (71)	5 (100)	0.4
Medical Hx:
-HTN (%)	10 (80)	6 (86)	4 (80)	1
-Tob. (%)	10 (80)	6 (86)	4 (80)	1
-DM (%)	1 (8)	1 (14)	0	1
-Hx IA (%)	1 (8)	0	1 (20)	0.4
-Fam. Hx IA (%)	1 (8)	1 (14)	0	0.4
Admission Data:
-Temp. (°C)	36.9 ± 0.4	37 ± 0.4	36.9 ± 0.4	0.7
-MAP (mmHg)	95.9 ± 15.1	100.4 ± 16.3	89.6 ± 12	0.2
-GCS ≤ 8 (%)	4 (33)	3 (43)	1 (20)	0.5
-Median HHS (IQR)	3.5 (1)	3 (2)	4 (1.5)	0.2
-Median mFS (IQR)	4 (1)	4 (1)	4 (1)	0.4
-Hb (gr/dl)	13.7 ± 1.9	14.2 ± 2.1	13.04 ± 0.6	0.2
-EF (%)	56.7 ± 10.8	57.5 ± 10.8	55.6 ± 12.1	0.6
In-hospital interventions:
-HHT days	–	6.1 ± 5.5	0	0.01*
-M vent. (%)	11 (92)	7 (100)	4 (80)	0.4
-Days M. Vent.	9.25 ± 7.1	12.4 ± 7.5	4.8 ± 3.4	0.04*
-EVD days	16.5 ± 6.3	17 ± 7.5	15.6 ± 4.7	0.6
-VPS (%)	6 (50)	3 (43)	3 (60)	1
Imaging data:
-Aneurysm size (mm)	6.15 ± 2.3	7.3 ± 20	4.4 ± 1.6	0.02*
-Aneurysm location: AC (%)	9 (75)	6 (86)	3 (60)	0.5
-CI (%)	8 (66)	5 (71)	3 (60)	1
-Deep CI (%)	4 (44)	3 (60)	1 (25)	0.5
ICU LOS (days)	14.6 ± 6.2	17.7 ± 6.1	10.4 ± 3.5	0.02*
Hosp. LOS (days)	24.4 ± 7.9	23.8 ± 8.4	25.2 ± 8.1	0.7
Discharge disposition:
-Acute rehab (%)	6 (50)	2 (28)	4 (80)	0.2
Functional outcome:
-90-d mRS ≤ 2 (%)	7 (58)	3 (43)	4 (80)	0.2

Unbound iron and iron-handling proteins concentration

We were able to obtain CSF on day 1 in only 6 patients due to either initially low ventriculostomy output, admission > 24 hours from onset of symptoms or emergent surgery or endovascular intervention precluding proper sample collection. For subsequent days (i.e. days 3 and 5), CSF was available for all 12 patients. Figure 1 depicts the change in unbound iron (i.e. NTBI and REDOX-Fe) concentration in CSF over the first 5 days following SAH. Values for NTBI and REDOX-Fe in control CSF were 0.12 ± 0.05 and 0.07 ± 0.02 μM (mean ± SEM), respectively. A significant increase in both NTBI and REDOX-Fe levels was observed over time, with a peak level that was about 10-fold that of control subjects (0.69 ± 0.07 vs. 0.07 ± 0.02 μM for REDOX-Fe and 1.07 ± 0.03 vs. 0.1 ± 0.03 μM for NTBI, p= 0.01), and a change in magnitude in concentration ranging between 120 and 170% from days 1 to 5 (0.41 ± 0.05 vs. 0.69 ± 0.07 μM for REDOX-Fe, p= 0.008; and 0.91 ± 0.28 vs. 1.07 ± 0.16 μM for NTBI, p= 0.08)

Figure 1.

Unbound CSF iron over first 5 days following SAH. Mean ± standard error of the mean depicted. Values for concentration of NTBI and REDOX-Fe in controls also provided. NTBI: non-transferrin bound iron; REDOX-Fe: redox-active iron.

Figure 2 depicts the changes in iron handling and regulating proteins over time. The mean ceruloplasmin (Cp) concentration in CSF samples from SAH patients on day 1 was almost 80 times higher than that of control subjects (134.9 ± 27.2 vs. 1.7 ± 0.7 mg/L; p= 0.04), but it decreased by the third day (55.3 ± 9.4 mg/L) and remained virtually unchanged through day 5 (55.5 ± 7.8 mg/L). The levels of REDOX-Fe were inversely related to the Cp concentration in a simple linear regression analysis (p= 0.03)

Figure 2.

Concentration of (a) ceruloplasmin, (b) ferritin, lactoferrin, (c) transferrin and (d) pro-hepcidin in cerebrospinal fluid over time. Values represented as mean ± standard error of the mean. Corresponding values in control CSF also provided.

The mean CSF ferritin (Ft) on day 1 in SAH patients was 877.6 ± 163.8 pmol/L, compared to 408.9 ± 87.6 pmol/L in controls (p= 0.1). Ferritin steadily increased and quadrupled by day 5 reaching a concentration of 3,534.5 ± 826.9 pmol/L (p= 0.01). Similarly, mean lactoferrin (Lf) levels were significantly higher in patients compared to controls (398 ± 77 vs. 0 μg/L; p= 0.004), and Lf spiked on day 3 in SAH patients and exhibited a small decrement in subsequent sampling. Transferrin (Tf) was also significantly elevated on the first day (0.02 ± 0.007 vs. 0.005 ± 0.001 g/L; p= 0.01), but CSF levels trended down over time and by day 5 they were similar to that of control subjects (0.007 ± 0.002 vs. 0.005 ± 0.001 g/L; p= 0.8); whereas Pro-hepcidin (Ph) levels were initially similar to those of control subjects, but progressively increased over the first five days after SAH (151 ± 29 Vs. 8.2 ± 3.2 μg/L in controls; p= 0.01).

Clinical and radiographic Outcomes

Delayed cerebral ischemia

A total of 7 patients (58%) met the pre-specified criteria for DCI. Development of DCI was associated with larger aneurysm size (p= 0.02), and expectedly longer duration of HHT (p= 0.01), prolonged mechanical ventilation (P= 0.04), and ICU LOS (P= 0.02) (table 1). As table 2 illustrates, these patients also had a significantly higher CSF NTBI on day 5 and mean NTBI than those who did not develop DCI (1.39 ± 0.17 vs. 0.62 ± 0.12 μM; p= 0.02 and 1.27 ± 0.17 vs. 0.62 ± 0.08 μM; p= 0.03, respectively). In an univariate logistic regression analysis, day 5 NTBI, peak NTBI, mean NTBI, day 3 Ft, day 1 Ph and day 3 Ph were significantly associated with the development of DCI, however in a multivariate analysis only day 5 NTBI, mean NTBI, and peak NTBI remained significant (p= 0.001).

Table 2.

Cerebrospinal fluid levels of unbound iron and iron-handling proteins in patients with SAH by delayed cerebral ischemia status. REDOX-Fe: redox active iron; NTBI: non-transferrin bound iron; Cp: ceruloplasmin.

	SAH (12) (Mean ± SEM)	Control (4) (Mean ± SEM)	p	DCI (Mean ± SEM)	No DCI (Mean ± SEM)	p
REDOX-Fe D1 (μM)	0.42 ± 0.05	–	–	0.48 ± 0.03	0.35 ± 0.1	0.6
REDOX-Fe D3 (μM)	0.65 ± 0.07	–	–	0.69 ± 0.08	0.55 ± 0.08	0.4
REDOX-Fe D5 (μM)	0.71 ± 0.08	–	–	0.75 ± 0.07	0.6 ± 0.1	0.4
Mean REDOX-Fe (μM)	0.64 ± 0.05	0.08 ± 0.01	0.01*	0.68 ± 0.07	0.55 ± 0.07	0.5
NTBI D1 (μM)	0.91 ± 0.29	–	–	1.36 ± 0.4	0.44 ± 0.2	0.1
NTBI D3 (μM)	0.98 ± 0.14	–	–	1.16 ± 0.2	0.7 ± 0.1	0.2
NTBI D5 (μM)	1.09 ± 0.16	–	–	1.4 ± 0.1	0.6 ± 0.1	0.02*
Mean NTBI (μM)	1.01 ± 0.14	0.12 ± 0.05	0.01*	1.27 ± 0.1	0.6 ± 0.08	0.03*
Mean Cp (mg/L)	69.4 ± 7.97	1.72 ± 0.72	0.04*	60.8 ± 11.4	81.37 ± 9.09	0.1
Mean Ferritin (pmol/L)	2323 ± 388	408.9 ± 87	0.004*	2864 ± 532	1566 ± 400	0.2
Mean Transferrin (g/L)	0.01 ± 0.003	0.005 ± 0.001	0.3	0.01 ± 0.004	0.01 ± 0.004	0.7
Mean Lactoferrin (μg/L)	398 ± 77	0	0.004*	416 ± 123	372 ± 83	1
Mean Pro-hepcidin (μg/L)	74 ± 14	8.2 ± 3.2	0.04*	92 ± 21	50 ± 17	0.3

Angiographic vasospasm

Five patients (41.6%) developed angiographic evidence of vasospasm. Only day 3 REDOX-Fe and mean REDOX-fe correlated with development of VSP on cerebral angiogram in a regression analysis (p= 0.02).

Cerebral ischemia

Nine patients (75%) underwent MRI scans and evidence of acute ischemia on DWI sequences was identified in 8 of them. Most strokes involved deep brain structures (%), and only one instance of exclusive cortical involvement was identified while the rest were a combination of cortical and deep strokes. Day 1 REDOX-Fe, day 1 Cp, day 3 Lf and change in Cp concentration between days 3 and 5 correlated with development of cerebral ischemia in univariate logistic regression, however only day 1 REDOX-Fe and change in Cp between days 3 and 5 remained significant in multivariate regression analysis (p= 0.02). Patients who developed deep cerebral infarcts had a significant lower level of Cp on day 3, compared to those who did not (34.1 ± 11.9 vs. 81.4 ± 14.2 mg/L; p= 0.03). The development of deep-seated strokes was associated with mean REDOX-Fe, day 3, day 5, and peak Cp, and day 5 and mean Tf in univariate logistic regression, but only mean REDOX-fe, day 3 Cp, day 5 Cp, peak Cp, and mean Tf remained significant in multivariate regression (p= 0.03).

Length of stay and discharge disposition

Patients who developed DCI had a significantly prolonged stay in the intensive care unit (17.7 ± 6.1 vs. 10.4 ± 3.5 days; p= 0.02), but the overall hospital LOS was similar between the two groups (23.8 ± 8.4 vs. 25.2 ± 8.1 days; p= 0.7) (table 1). Most patients (42%) were discharged to an acute rehabilitation facility, whereas 33% went to a skilled nursing facility (SNF) and 16% to a long-term acute care facility (LTAC). Only 8% of patients were discharged directly home from the hospital to their homes.

Functional outcomes (dichotomized 90-day mRS)

A total of 7 patients (58%) had a mRS score of 2 or less at 90 ± 18 days. Patients who developed DCI were more likely to have poor functional outcomes (i.e. 90-day mRS > 2) than patients who did not (57% vs. 20%; p 0.2), but this difference did not reach statistical significance (table 1). Overall, patients in the favorable outcome group had lower mean REDOX-Fe concentrations in CSF (0.53 ± 0.05 vs. 0.77 ± 0.05 μM; p= 0.05). Subjects in the favorable outcome group also had lower levels of Lf (320 ± 60 vs. 532 ± 153 μg/L; p= 0.1) and Ft (1,804.3 ± 478.6 vs. 3,051.4 ± 541.5 pmol/L; p= 0.1), and higher mean Cp concentration in CSF (80.2 ± 5.9 vs. 54.3 ± 15.8 mg/L; p= 0.1), but none of these differences were statistically significant.

Discussion

In this small pilot study, we found that measures of unbound iron (NTBI and REDOX-Fe) in the CSF of patients with SAH were higher than in controls, and that their concentrations rose over the first 5 days following ictus. We also found that development of DCI, angiographic vasospasm, and presence of cerebral ischemia on DWI-MRI was associated with higher concentration of non-protein bound iron in CSF, while patients who developed ischemic strokes had lower CSF ceruloplasmin levels.

Following aneurysm rupture, a large amount of blood is released into the subarachnoid space.¹⁶ Phagocytosis and breakdown of red blood cells (RBCs) occur by 16–32 hours¹⁷ and hemoglobin rapidly distributes over the entire brain and easily penetrates the deeper layers of the cortex.¹⁸ Iron, a byproduct of heme degradation by heme-oxygenase 1, can react with H₂O₂ via the Fenton reaction to form reactive oxygen species (ROS)¹⁹ that have been shown to mediate vasoconstriction, arterial structural damage, microcirculatory derangement and neurotoxicity in experimental SAH.^{8, 17, 20} While the mechanisms normally responsible for iron homeostasis in the CNS have not been fully elucidated (Benarroch 2009), considering the amount of iron released after RBCs lysis, it is likely that many of these become quickly saturated. For instance, CSF has a low iron-binding capacity that is close to saturation under normal conditions⁵ and the increase in the labile iron pool following brain injury has been shown to be too large to be sequestered by cellular ferritin.¹⁹

Coexistence of ROS and iron deposits in periarterial spaces, the tunica adventicia of cerebral arteries and infiltrating neutrophils in experimental SAH supports the hypothesis that iron-mediated generation of ROS results in cerebral vasospasm.⁸ Furthermore, iron may facilitate the formation of bilirubin oxidation products (BOXes) that have been postulated to play a role in arterial vasoconstriction.²¹ Iron and ROS have also been linked to blood brain barrier dysfunction and brain edema formation through activation of matrix metalloproteinase-9.²² A progressive increase in brain non-heme iron following SAH leading to increased intracellular deposits has been implicated in oxidative DNA injury and activation of autophagic and apoptotic cell death pathways,^{16, 23} and prolonged ferritin elevation within neurons is known to lead to cell death.²⁴ In contrast, the use of iron-chelating agents can effectively prevent the development of cerebral vasospasm following experimental SAH.^{25, 26} We decided to examine the role of unbound and redox-active iron, as opposed to total CSF iron, since in a previous investigation it did not correlate with the development of cerebral vasospasm (Suzuki 2003), and because preliminary data from animal studies suggest that redox-active iron-mediated production of superoxide anion strongly correlated with development of vasospasm (Mori 2012). Our findings add to the accumulating evidence implicating iron-mediated toxicity as a major contributor to the pathophysiology of acute brain injury following SAH.

The prevention of vasospasm through ferritin-mediated iron detoxification has been postulated recently.²⁷ While it is primarily an intracellular protein, in pathological conditions Ft is secreted into the CSF where it may help clear iron released following red cell lysis. The Ft concentration in CSF of SAH patients in our study was very similar to that reported previously (3,534.5 ± 826.9 vs. 3,509.8 ± 563.9 pmol/L), however we did not observe a significant difference between DCI and no DCI groups. This lack of correlation may be due to the small number of patients included in our study, but also to the use of different endpoints (DCI versus transcranial Doppler and Xenon CT scan) between our investigation and the one reported by Suzuki et al.27 The exact role that Ft plays in the metabolism of iron following SAH remains to be firmly established.

Earlier studies had implicated a role for Tf in the pathogenesis of cerebral vasospasm through a mechanism involving increased cytosolic free calcium in smooth muscle cells. Moreover, significantly elevated CSF levels have been recently described in patients who developed this condition.^{28, 29} We could not replicate these findings and CSF Tf, while elevated in SAH patients, trended down over time and no significant difference by DCI status was observed. It is important to note that we measured Tf levels at an earlier time frame and that may at least partially account for this discrepancy. Whether transferrin plays any significant role in the pathogenesis of brain injury following aneurysmal SAH remains to be elucidated.

Lactoferrin is a small iron-binding glycoprotein found in various secretory fluids, where it serves primarily an antimicrobial function (Marrif 2009). It has also been found to have anti-inflammatory, anti-oxidant, anti-tumorigenic, and transcription effects (Hirsch 1998), which seem to be modulated by its ability to donate and sequester iron. Moreover, CSF lactoferrin levels were found to be elevated in patients following both ischemic and hemorrhagic stroke (Terent 1981). In our study, Lf levels did not correlate with any of the outcomes studied and therefore seems unlikely to play a major role in the body’s response to SAH.

We also sought to explore whether hepcidin played a role in brain iron metabolism following SAH. Hepcidin is secreted primarily by hepatocytes in response to inflammatory stimuli, iron, and hypoxia and is responsible for the regulation of body iron balance. It has also been shown to be widely expressed in the murine brain (Wang 2010). It is initially synthesized as a prepropeptide, which is in turn processed into a 60- to 64-residue prohepcidin peptide, and then finally into the mature and biologically active 25-amino acid hepcidin. We chose to determine pro-hepcidin levels due to the ubiquitous availability of enzyme-linked immunoassays (Frazer 2009). In our small pilot study pro-hepcidin did not correlate with any of the outcomes explored. It remains to be seen whether determination of hepcidin-25 levels with recently available immunoassays affect the development of DCI, vasospasm or cerebral infarcts following aneurysmal SAH.

Ceruloplasmin is a serum alpha-2 glycoprotein that belongs to the family of multi-copper oxidase enzymes.³⁰ It is an acute phase reactant with a number of attributed functions including, ferroxidase activity;³¹ antioxidant functions and the prevention of the formation of free radicals;³² inhibition of neutrophil myeloperoxidase;³³ and protective anti-inflammatory roles, among others.³⁴ Interestingly, patients with aceruloplasminemia, an autosomal recessive disorder characterized by mutations that abolish functional Cp and impair iron homeostasis, exhibit abundant iron deposition in microglia and neurons, selective neuronal loss and evidence of increased ROS generation in the CNS.³⁵ Moreover, brains of adult transgenic Cp^−/− mice show evidence of increased lipid peroxidation and free radical-mediated injury, intracellular iron accumulation and increased susceptibility to free radical injury.³⁶ Interestingly, we found Cp levels to be significantly and inversely correlated with REDOX-Fe concentration in CSF. Also, lower CSF ceruloplasmin levels were associated with higher likelihood of ischemic strokes, particularly in deep locations. To our knowledge, a potential protective effect of Cp in SAH has not been explored before.

This study has some limitations. First, given the small number of patients included, these findings need to be considered preliminary and require further validation in a larger cohort of patients; furthermore, the sample size significantly limits the validity of multivariate analysis. Second, CSF on day 1 was only available in half of the patients in our analysis, considerably diminishing the number of samples available for testing. Third, control CSF was obtained from patients as part of the work up for normal pressure hydrocephalus and may not represent truly normal CSF. Furthermore, we do not have demographic data available for this cohort. Finally, We were unable to obtain serial MRI-DWI imaging in this cohort and instead reviewed MRIs obtained as part of clinical care, which could potentially have introduced biases.

In conclusion, our preliminary data indicate a causal relationship between unbound iron and brain injury following SAH and suggest a possible protective role for Ceruloplasmin in this setting, particularly in the prevention of cerebral ischemia. Further studies are needed to validate these findings and to probe their clinical significance.