Exploring the exogenous and endogenous effects of melatonin on spinal cord injury

Introduction

Spinal cord injury (SCI) is a catastrophic incident with a global mortality rate ranging from 4.4% to 16.7%, often leading to neurological disability ( ). Traumatic injury to the spinal cord induces death in a number of local neurons and glia at the lesion site that cannot be recovered or regenerated. The mechanisms of secondary injury begin immediately after the primary insult and continue for weeks or months via a diverse array of pathophysiological processes, including inflammation, excitotoxicity, and oxidative cell damage ( ). These secondary insults lead to further destruction of neuronal and glial cells and to massive extension of the damage whereby the paralysis can extend to higher segments.

Disruption of circadian rhythm is a common feature in SCI individuals. Circadian misalignment can increase neuronal death, resulting in deterioration of sensorimotor functions and cognitive deficits ( ). In experimental studies, SCI was shown to lead to wide-ranging circadian rhythm disruption, including dysregulated rhythms of body temperature, and inflammatory gene expression ( ). Besides, circulating levels of serum melatonin (MT) has been altered in patients with cervical SCI ( ), suggesting alteration of diurnal rhythms negatively influencing the SCI recovery process.

As SCI results in permanent or long-term disability and poor quality of life, it imposes an enormous financial burden on society in terms of increased healthcare costs and decreased productivity ( ). Although efforts are currently being pursued to develop novel therapeutics to combat the pathogenesis of SCI, the effects of these interventions are generally limited. For example, exercise interventions, which are widely used to improve functional recovery following SCI, have an inadequate ability to improve motor function after SCI ( ).

MT is a neurohormone that is synthesized and released from the pineal gland in a 24-h diurnal pattern and exerts its actions in peripheral tissues. This pineal hormone is best known for maintaining the 24-h internal clock and has excellent antioxidant capacity ( ). MT exerts beneficial effects by altering the levels of oxidative stress markers, including malondialdehyde (MDA), glutathione (GSH), superoxide dismutase (SOD), and myeloperoxidase, which are generally reported to show abnormalities with progression of SCI ( ; ). MT has other biological functions in SCI, including reduction of pro-inflammatory molecules ( ) and regulation of autophagy ( ). Recently, we demonstrated that a significant reduction in endogenous MT levels disrupted neural remodeling, and homeostasis of endogenous MT levels contributed to excitatory synaptic formation and axonal outgrowth in a rodent model of SCI ( ), indicating MT replacement strategies improve the neuronal repair process following SCI.

In this chapter, we explore the promising molecular mechanisms of MT intervention that may be beneficial in the management of SCI. We discuss MT and exercise combination therapy in SCI. Finally, we also discuss the crucial role of endogenous MT, which may influence the recovery process after SCI.

Effects of exogenous melatonin on secondary injury after spinal cord injury

Neuronal death caused by primary injury from SCI cannot be prevented. Therefore, current research focuses on preventing the secondary injury cascade to mitigate progressive tissue damage, representing a novel strategy for the management of SCI pathology. The timeline of major pathological events of secondary injury and timeline-specific therapeutic strategies are shown in Fig. 1 . In this section, we will discuss recent findings on the effects of exogenous MT on SCI, particularly the neuroprotective mechanism of action of MT in secondary injury events.

Effects of exogenous melatonin on oxidative stress

Pre-clinical research in animal models has reported that increased production of reactive oxygen species (ROS) and the consequent oxidative stress are crucial pathological events in SCI, which lead to neurological deficits. Oxidative stress is a hallmark of the secondary injury in SCI. Much of the current literature on secondary injury after SCI has focused particularly on oxidative stress because down-regulation of its detrimental effects is considered a key strategy for therapeutic interventions ( ). After SCI, oxidative stress may increase the level of lipid peroxidation (LPO) ( ), as determined by quantifying the levels of MDA, GSH, and SOD. Electron resonance spectrometry was used to measure MDA levels and provided the first lines of evidence for ROS production in SCI. Seligman et al. reported that the level of MDA was significantly increased within the first 5 h following SCI. A recent study showed that the MDA level increased markedly after 1 day and peaked at 7 days after SCI ( ). SOD activity was decreased at 1 day following SCI ( ). Previous studies showed that MT and its derivatives scavenge free radicals and induce the activities of various antioxidant enzymes. Erşahin et al. investigated the impact of MT in a rat model of standard weight drop-induced moderate SCI and showed that MT significantly restored the MDA and GSH levels. Immediately after laminectomy, treatment of SCI rats with MT once daily for 10 days also resulted in restored GSH levels ( ). In addition, the pathophysiological mechanism was proposed to involve iron-catalyzed LPO contributing to autodestruction in the injured spinal cord regions ( ). Previous research established that ferrous iron can initiate brain LPO ( ). After SCI, the levels of free iron and MDA were significantly increased but markedly decreased by MT treatment ( ). investigated the effects of MT, prostaglandin E1, and oxytetracycline on LPO and antioxidant activities in an experimental model of SCI. The results showed that experimentally induced SCI reduced erythrocyte SOD and plasma GSH activities and increased tissue and blood MDA levels ( ). These physiological alterations were inhibited by MT, prostaglandin E1, and oxytetracycline treatments to varying degrees, with MT showing the greatest effect ( ). Taken together, pre-clinical trials suggest that MT may exert neuroprotective effects on SCI by reducing oxidative stress and promoting functional recovery after SCI ( Fig. 2 ).