The Endocannabinoid System, Our Universal Regulator

The Endocannabinoid System Structure and Function With all the complex cell signals, genetic mutations, and outside influences, how do we manage to stay at homeostasis? The answer is the endocannabinoid system. It is present nearly everywhere in the human body and functions by maintaining the homeostasis of the human body (Alger, 2013). This is achieved through a negative feedback loop which works by the activation of a postsynaptic neuron synthesizing and releasing the endocannabinoids as they target various cannabinoid (CB) receptors. These CB receptors are G-protein-coupled receptors (Gambi et al., 2005), which allow them to directly influence the incoming signals. This functions as an “override” signal, which differs from most other cells. As other cells have signal modifiers that can do anything from amplifying to diverging signals, the neuron is “over-riding” those cells. For example, a fracture in the toe would result in cell death. The resulting lymphatic response would increase blood flow and the migration of white blood cells to the surrounding areas. The ECS would then recognize the excess lymphatic signals, and after deciding that there is no longer a need for the increase of inflammation, the CB receptors in the surrounding immune cells and tissues will begin to bind with cannabinoids and start to slowly reduce these inflammatory responses. A similar process occurs with pain signals in the brain. The binding and stimulation of CB1 receptors will upregulate the gamma-aminobutyric acid (GABA) neurotransmitters, thereby reducing pain signals throughout the brain. There are two main receptors in the ECS: the CB1 and CB2 receptors. CB1 receptors are located primarily within brain cells (including but not limited to the hippocampus, amygdala, and hypothalamus), and are not as densely expressed in the CNS, PNS, and the immune system. On the other hand, the CB2 receptors are located primarily in the CNS, PNS, immune system, and within white blood cells. Additionally, the existence of CB3 receptors is also hypothesized (Iqbal, 2007). These INTRODUCTION Despite various medical advances, there are still many more functions of the human body to uncover. Some of the less effective treatments lie within the field of mental health, due to the lack of accuracy and availability of tests for neurotransmitter function as well as apoptotic activity. The existing neurotransmitter tests utilize metabolites in urine (Hinz, Stein, Trachte, & Ucini 2010); however, their applicability is currently very limited. We have not been able to show that the neurotransmitter levels measured in urine are as accurate as the actual levels in the central nervous system (CNS) or peripheral nervous system (PNS). Apoptotic diseases such as cancer, acquired immune deficiency syndrome (AIDS), ALS, and autism, are all without an effective cure at the moment, and they seem to have similar pathology which involves neurotransmitter, mitochondrial, and apoptotic dysfunction (Favaloro, Allocati, Graziano, Di Lio, & De Laurenzi 2012). The ECS, unlike the CNS, PNS, and circulatory system, is one of the most understudied systems in the human body. It has been documented that ECS is directly involved with various roles in apoptosis, neurotransmitter levels, and homeostasis (Basavarajappa, Nixon, & Arancio, 2009). ECS seems to carry a stigma because of the word “cannabis.” In this paper, functions and possible benefits of ECS will be discussed. The Endocannabinoid System, Our Universal Regulator