Abstract
Melatonin (MEL) is a hormone that is produced in the brain and is known to bind to MEL-specific receptors on neuronal membranes in several brain regions. MEL’s documented neuroprotective properties, low toxicity, and ability to cross the blood-brain-barrier have led to its evaluation for patients with traumatic brain injury (TBI), a condition for which there are currently no Food and Drug Administration (FDA)-approved therapies. The purpose of this manuscript is to summarize the evidence surrounding the use of melatonin after TBI, as well as identify existing gaps and future directions. To address this aim, a search of the literature was conducted using Pubmed, Google Scholar, and the Cochrane Database. In total, 239 unique articles were screened, and the 22 preclinical studies that met the a priori inclusion/exclusion criteria were summarized, including the study aims, sample (size, groups, species, strain, sex, age/weight), TBI model, therapeutic details (preparation, dose, route, duration), key findings, and conclusions. The evidence from these 22 studies was analyzed to draw comparisons across studies, identify remaining gaps, and suggest future directions. Taken together, the published evidence suggests that MEL has neuroprotective properties via a number of mechanisms with few toxic effects reported. Notably, available evidence is largely based on data from adult male rats and, to a lesser extent, mice. Few studies collected data beyond a few days of the initial injury, necessitating additional longer-term studies. Other future directions include diversification of samples to include female animals, pediatric and geriatric animals, and transgenic strains.
Highlights
Traumatic brain injury (TBI) affects countless individuals worldwide [1,2,3,4,5,6,7,8,9], with an estimated 2.5 million cases in the United States during 2010 alone [1]
The studies analyzed a variety of TBI conditions, ranging from mild (Tables A7 and A21) to moderate (Tables A3 and A17)
Five of the studies [34,39,45,46] tested the effects of MEL in combination with another drug and found the effects of combined therapy were superior to the effects of either drug alone; this is consistent with a growing body of evidence that two or more drugs in combination may be needed to adequately treat TBI [52]
Summary
Traumatic brain injury (TBI) affects countless individuals worldwide [1,2,3,4,5,6,7,8,9], with an estimated 2.5 million cases in the United States during 2010 alone [1]. While the therapeutic effects of MEL in human TBI remain understudied, MEL has demonstrated beneficial effects in pre-clinical models of several CNS disorders, including conditions with similar pathology and symptoms profiles, to TBI such as: Huntington’s disease [20], Alzheimer’s disease [21], amyotrophic lateral sclerosis [22,23], stroke [24,25], sepsis-induced brain dysfunction [21], and spinal cord injury [26,27]. It is possible that in the context of TBI, MEL will have similar improvements in secondary injury pathways and reduce symptom burden, which may contribute to other beneficial outcomes such as earlier return to play for sports-related injuries
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