Haemoglobin causes neuronal damage in vivo which is preventable by haptoglobin

Patrick Garland,Ardalan Zolnourian,John More,Ian Galea,Andrew Durnford,William Haskins,Jamie Toombs,Jessica L Teeling,Amanda J Heslegrave,Ben Gaastra,Matthew J Morton,Azubuike I Okemefuna,Diederik O Bulters,Soren K Moestrup,Henrik Zetterberg,Jonas H Graversen

doi:10.1093/braincomms/fcz053

Abstract

After subarachnoid haemorrhage, prolonged exposure to toxic extracellular haemoglobin occurs in the brain. Here, we investigate the role of haemoglobin neurotoxicity in vivo and its prevention. In humans after subarachnoid haemorrhage, haemoglobin in cerebrospinal fluid was associated with neurofilament light chain, a marker of neuronal damage. Most haemoglobin was not complexed with haptoglobin, an endogenous haemoglobin scavenger present at very low concentration in the brain. Exogenously added haptoglobin bound most uncomplexed haemoglobin, in the first 2 weeks after human subarachnoid haemorrhage, indicating a wide therapeutic window. In mice, the behavioural, vascular, cellular and molecular changes seen after human subarachnoid haemorrhage were recapitulated by modelling a single aspect of subarachnoid haemorrhage: prolonged intrathecal exposure to haemoglobin. Haemoglobin-induced behavioural deficits and astrocytic, microglial and synaptic changes were attenuated by haptoglobin. Haptoglobin treatment did not attenuate large-vessel vasospasm, yet improved clinical outcome by restricting diffusion of haemoglobin into the parenchyma and reducing small-vessel vasospasm. In summary, haemoglobin toxicity is of clinical importance and preventable by haptoglobin, independent of large-vessel vasospasm.

Highlights

After subarachnoid haemorrhage (SAH), blood is released into the subarachnoid space (Macdonald and Schweizer, 2017)
We focussed on an initial two-week time interval, during which we serially sampled CSF and investigated whether there was a temporal relationship between Hb and neurofilament light chain (NFL), a marker of neuronal damage (Siedler et al, 2014)
Control CSF was collected by lumbar puncture in patients with non-inflammatory non-haemorrhagic neurological symptoms

Summary

Introduction

After subarachnoid haemorrhage (SAH), blood is released into the subarachnoid space (Macdonald and Schweizer, 2017). As the blood clot in the subarachnoid space is resorbed, red blood cell (RBC) lysis leads to the release of cell-free haemoglobin (Hb) over a protracted period exerting a further secondary, and potentially reversible, injury. Less is known about the neurological consequences of prolonged exposure to lower concentrations of Hb distributed throughout the ventricular system, as happens during clot lysis after SAH. Repeated cisterna magna injections of washed autologous red blood cells in rabbits caused iron deposition and a microglial reaction in the cerebellum, but neuronal integrity and behavioural deficits were not studied (Koeppen and Borke, 1991). A single intraventricular Hb injection in 7 day old neonatal rats caused neuronal damage (Garton et al, 2016), so a similar process could occur after prolonged exposure to subarachnoid Hb in adults

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