The habenula (diminutive of Latin habena meaning rein) is a small bilateral neuronal structure in the brain of vertebrates, that has also been called a microstructure since it is no bigger than a pea. The naming as little rein describes its elongated shape in the epithalamus, where it borders the third ventricle, and lies in front of the pineal gland.[1]
Although it is a microstructure each habenular nucleus is divided into two distinct regions of nuclei, a medial habenula (MHb), and a lateral habenula (LHb) both having different neuronal populations, inputs, and outputs.[2][3] The medial habenula can be subdivided into five subnuclei, the lateral habenula into four subnuclei.[4] Research has shown morphological complexity in the MHb and LHb. Different inputs to the MHb are discriminated between the different subnuclei.[5] In the two regions of nuclei there is a difference in gene expression giving different functions to each.[6]
The habenula is a conserved structure across vertebrates. In mammals it is highly symmetric, and in fish, amphibians and reptiles it is highly asymmetric in size, molecular composition, and connections.[1] The habenular nuclei are a major component in the limbic system pathways.[1] The fasciculus retroflexus pathway between the habenula and the interpeduncular nucleus is one of the first major nerve tracts to form in the developing brain.[1]
The habenula is a central structure that connects forebrain regions to midbrain regions, and acts as a hub or node for the integration of emotional and sensory processing.[2] It integrates information from the limbic system, sensory and basal ganglia to guide appropriate and effective responses.[5] The habenula is involved in the regulation of monoamine neurotransmitters notably dopamine and serotonin.[2][3] Both of these neurotransmitters are strongly associated with anxiety disorders, and avoidance behaviours.[2] The functions of the habenula are also involved in motivation, emotion, learning, and pain.[2] The MHb plays an important role in depression, stress, memory, and nicotine withdrawal, as well as a role in cocaine, methamphetamine and alcohol addiction.[6] The MHb shows a high level of nicotinic acetylcholine receptors (nAChRs), that are involved in many forms of addiction. Previously their expression was only noted in other structures associated with addiction. Their expression in the MHb has become a later focus of research.[6]
The primary input regions to the lateral habenula (LHb) are the lateral preoptic area (bringing input from the hippocampus and lateral septum), the ventral pallidum (bringing input from the nucleus accumbens and mediodorsal nucleus of the thalamus), the lateral hypothalamus, the medial habenula, and the internal segment of the globus pallidus (bringing input from other basal ganglia structures).[8]
Neurons in the lateral habenula are 'reward-negative' as they are activated by stimuli associated with unpleasant events, the absence of the reward or the presence of punishment especially when this is unpredictable.[11] Reward information to the lateral habenula comes from the internal part of the globus pallidus.[12]
The outputs of the lateral habenula target dopaminergic regions (substantia nigrapars compacta and the ventral tegmental area), serotonergic regions (median raphe and dorsal raphe nuclei), and a cholinergic region (the laterodorsal tegmental nucleus).[8] This output inhibits dopamine neurons in substantia nigra pars compacta and the ventral tegmental area, with activation in the lateral habenula linking to deactivation in them, and vice versa, deactivation in the lateral habenula with their activation.[13] The lateral habenula functions to oppose the action of the laterodorsal tegmental nucleus in the acquisition of avoidance responses but not the processing of avoidance later on when it is a memory, motivation or its execution.[14] Research suggests that lateral habenula may play a crucial role in decision making.[15]
There has also shown to be an association with aberrant LHb activity and depression.[16]
Asymmetry in the habenula was first noted in 1883 by Nikolaus Goronowitsch.[7] Various species exhibit left-right asymmetric differentiation of habenular neurons. In many fishes and amphibians, the habenula on one side is significantly larger and better organized into distinct nuclei in the dorsal diencephalon than its smaller pair. The sidedness of such differentiation (whether the left or the right is more developed) varies with the species. In birds and mammals, however, both habenulae are more symmetrical (although not entirely) and consist of a medial and a lateral nucleus on each side which is in fish and amphibians equivalent to dorsal habenula and the ventral habenula, respectively.[19][8][20]
Olfactory coding
In some fish (lampreys and teleosts), mitral cell (principal olfactory neurons) axons project exclusively to the right hemisphere of the habenula in an asymmetric manner. It is reported that the dorsal habenula (DHb) are functionally asymmetric with predominantly odor responses in the right hemisphere. It was also shown that DHb neurons are spontaneously active even in the absence of olfactory stimulation. These spontaneously-active DHb neurons are organized into functional clusters which were proposed to govern olfactory responses.[21]
Functions
These nuclei are hypothesized to be involved in regulation of monoamines, such as dopamine and serotonin.[22][23]
The habenular nuclei are involved in pain processing, reproductive behavior, nutrition, sleep-wake cycles, stress responses, and learning. Recent demonstrations using fMRI[24] and single unit electrophysiology[13] have closely linked the function of the lateral habenula with reward processing, in particular with regard to encoding negative feedback or negative rewards. Matsumoto and Hikosaka suggested in 2007 that this reward and reward-negative information in the brain might "be elaborated through the interplay among the lateral habenula, the basal ganglia, and monoaminergic (dopaminergic and serotonergic) systems" and that the lateral habenula may play a pivotal role in this "integrative function".[13] Then, Bromberg-Martin et al. (2011) highlighted that neurons in the lateral habenula signal positive and negative information-prediction errors in addition to positive and negative reward-prediction errors.[25]
Depression
Both the medial and lateral habenula show reduced volume in those with depression. Neuron cell numbers were also reduced on the right side.[26] Such changes are not seen in those with schizophrenia.[26]Deep brain stimulation of the major afferent bundle (i.e., stria medullaris thalami) of the lateral habenula has been used for treatment of depression where it is severe, protracted and therapy-resistant.[27][28]
N-Methyl-D-aspartate (NMDA) receptor-dependent burst firing in the lateral habenula has been associated with depression in animal studies,[29] and it has been shown that the general anesthetic ketamine blocks this firing by acting as a receptor antagonist.[30] Ketamine has been the subject of numerous studies after having shown fast-acting antidepressant effects in humans (in a 0.5 mg/bw kg dose).[31]
Motivation and addiction
Recent exploration of the habenular nuclei has begun to associate the structure with an organism's current mood, feeling of motivation, and reward recognition.[32] Previously, the LHb has been identified as an "anti-reward" signal, but recent research suggests that the LHb helps identify preference, helping the brain to discriminate between potential actions and subsequent motivation decisions.[33] In a study using a Pavlovian conditioning model, results showed an increase in the habenula response.[34] This increase coincided with conditioned stimuli associated with more aversive punishments (i.e. electric shock).[34] Therefore, researchers speculate that inhibition or damage to the LHb resulting in a failure to process such information may lead to random motivation behavior.[33][34]
LHb is especially important in understanding the reward and motivation relationship as it relates to addictive behaviors.[32] The LHb inhibits dopaminergic neurons, decreasing the release of dopamine.[35] It was determined by several animal studies that receiving a reward coincided with elevated dopamine levels, but once the learned association was learned by the animal, dopamine levels remain elevated, only decreasing when the reward is removed.[20][23][32][35] Therefore, dopamine levels only increase with unpredicted rewards and with a "positive prediction error".[20] Moreover, it was determined that removal of an anticipated award activated LHb, inhibited dopamine levels.[20] This finding helps explain why addictive drugs are associated with elevated dopamine levels.[20]
Nicotine and nAChRs
According to the National Institute on Drug Abuse, one in five preventable deaths in the United States is caused by tobacco use.[36]Nicotine is the addictive drug found in most tobacco products and is easily absorbed by the bloodstream of the body.[36] Despite common misconceptions regarding the relaxing effects of tobacco and nicotine use, behavioral testing in animals has demonstrated nicotine to have an anxiogenic effect.[37]Nicotinic acetylcholine receptors (nAChRs) have been identified as the primary site for nicotine activity and regulate consequent cellular polarization.[38] nAChRs are made up a number of α and β subunits and are found in both the LHb and MHb, where research suggests they may play a key role in addiction and withdrawal behaviors.[38][39]
History
The habenular is a well conserved structure that appeared in vertebrates more than 360 million years ago.[4] The habenular commissure was described for the first time in 1555 by Andreas Vesalius[40] and the habenula nuclei in 1872 by Theodor Hermann Meynert.[41]
^ abGuglielmotti, Vittorio; Cristino, Luigia (2006). "The interplay between the pineal complex and the habenular nuclei in lower vertebrates in the context of the evolution of cerebral asymmetry". Brain Research Bulletin. 69 (5): 475–488. doi:10.1016/j.brainresbull.2006.03.010. ISSN0361-9230. PMID16647576. S2CID24786037.
^Lecourtier L, Kelly PH (January 2007). "A conductor hidden in the orchestra? Role of the habenular complex in monoamine transmission and cognition". Neuroscience and Biobehavioral Reviews. 31 (5): 658–72. doi:10.1016/j.neubiorev.2007.01.004. PMID17379307. S2CID12856377.
^ abRanft K, Dobrowolny H, Krell D, Bielau H, Bogerts B, Bernstein HG (April 2010). "Evidence for structural abnormalities of the human habenular complex in affective disorders but not in schizophrenia". Psychological Medicine. 40 (4): 557–67. doi:10.1017/S0033291709990821. PMID19671211. S2CID11799795.
^Sartorius A, Kiening KL, Kirsch P, von Gall CC, Haberkorn U, Unterberg AW, Henn FA, Meyer-Lindenberg A (January 2010). "Remission of major depression under deep brain stimulation of the lateral habenula in a therapy-refractory patient". Biological Psychiatry. 67 (2): e9–e11. doi:10.1016/j.biopsych.2009.08.027. PMID19846068. S2CID43590983.
^Juckel G, Uhl I, Padberg F, Brüne M, Winter C (February 2009). "Psychosurgery and deep brain stimulation as ultima ratio treatment for refractory depression". European Archives of Psychiatry and Clinical Neuroscience. 259 (1): 1–7. doi:10.1007/s00406-008-0826-7. PMID19137233. S2CID27076192.
^Turliuc, Dana; Turliuc, Șerban; Cucu, Andrei; Dumitrescu, Gabriela; Costea, Claudia (2015-11-19). "An entire universe of the Roman world's architecture found in the human skull". Journal of the History of the Neurosciences. 26 (1): 88–100. doi:10.1080/0964704x.2015.1099382. ISSN0964-704X. PMID26584250. S2CID21254791.
^Turliuc, Dana; Turliuc, Şerban; Cucu, Andrei; Dumitrescu, Gabriela Florenţa; Cărăuleanu, Alexandru; Buzdugă, Cătălin; Tamaş, Camelia; Sava, Anca; Costea, Claudia Florida (2016). "A review of analogies between some neuroanatomical terms and roman household objects". Annals of Anatomy - Anatomischer Anzeiger. 204: 127–133. doi:10.1016/j.aanat.2015.07.001. ISSN0940-9602. PMID26337365.