Benzodiazepines

The onset of a benzodiazepine is often described as a gentle wave of calm that washes over you without any particular fanfare. Within 20 to 40 minutes of an oral dose, the persistent background hum of anxiety begins to soften and recede, as if someone slowly turned the volume dial down on the worrying part of your mind. Muscles that you did not realize you were clenching -- jaw, shoulders, lower back -- start to release, and you may notice a pleasant physical loosening that settles across the body.

Mentally, the experience is one of quieting. Thoughts that normally race or loop seem to slow to a manageable pace. There is a warmth to this that many compare to the first drink of alcohol: a social ease, a willingness to talk and engage without the usual second-guessing. Conversations feel lighter. Self-consciousness fades. At therapeutic doses, this is often where the effect levels off -- a functional calm that lets you go about your day without being hampered by intrusive anxiety.

At higher or recreational doses, the sedation component becomes more prominent. You may find yourself sinking into the couch, eyelids growing heavy, and the desire to simply rest becoming irresistible. Time starts to blur. This is where one of the most characteristic and dangerous effects emerges: anterograde amnesia. You may continue functioning -- talking, texting, even going places -- but wake up the next day with large gaps where memories should be. This "blackout" phenomenon is not like alcohol blackout; it can occur while you appear relatively sober to others, which makes it particularly insidious.

There is an important distinction between the therapeutic relief that benzodiazepines provide and the recreational pursuit of their effects. For someone with genuine clinical anxiety or panic disorder, a properly dosed benzodiazepine can feel like finally being able to breathe after holding your breath for months. The emotional blunting is not numbness so much as relief -- the sharp edges of panic are rounded off, and the world feels manageable again. Recreational use tends to push past this point into heavier sedation and disinhibition, where judgment deteriorates and the compulsion to redose becomes strong.

The redose compulsion deserves special emphasis. Because benzodiazepines impair judgment and memory simultaneously, many people take additional doses without remembering that they already dosed, or simply because the drug has lowered their concern about taking more. This is the primary mechanism by which benzodiazepine overdoses and dangerous interactions occur. Combining with alcohol or opioids at this stage can be fatal, as respiratory depression compounds.

Coming down is usually gradual rather than abrupt. The calm fades over several hours, sometimes replaced by a mild rebound anxiety that feels slightly worse than baseline. With occasional use this rebounds and resolves within a day. With regular use, withdrawal can be severe and medically dangerous -- one of the few drug classes where abrupt cessation can cause life-threatening seizures. Anyone using benzodiazepines regularly should taper under medical supervision rather than stopping abruptly.

Pharmacodynamics Benzodiazepines work by increasing the effectiveness of the endogenous chemical, GABA, to decrease the excitability of neurons. This reduces the communication between neurons and, therefore, has a calming effect on many of the functions of the brain.

GABA controls the excitability of neurons by binding to the GABAA receptor. The GABAA receptor is a protein complex located in the synapses between neurons. All GABAA receptors contain an ion channel that conducts chloride ions across neuronal cell membranes and two binding sites for the neurotransmitter gamma-aminobutyric acid (GABA), while a subset of GABAA receptor complexes also contain a single binding site for benzodiazepines. Binding of benzodiazepines to this receptor complex does not alter binding of GABA. Unlike other positive allosteric modulators that increase ligand binding, benzodiazepine binding acts as a positive allosteric modulator by increasing the total conduction of chloride ions across the neuronal cell membrane when GABA is already bound to its receptor. This increased chloride ion influx hyperpolarizes the neuron's membrane potential. As a result, the difference between resting potential and threshold potential is increased, and firing is less likely. Different GABAA receptor subtypes have varying distributions within different regions of the brain and, therefore, control distinct neuronal circuits. Hence, activation of different GABAA receptor subtypes by benzodiazepines may result in distinct pharmacological actions. In terms of the mechanism of action of benzodiazepines, their similarities are too great to separate them into individual categories such as anxiolytic or hypnotic. For example, a hypnotic administered in low doses produces anxiety-relieving effects, whereas a benzodiazepine marketed as an anti-anxiety drug at higher doses induces sleep.

The subset of GABAA receptors that also bind benzodiazepines are referred to as benzodiazepine receptors (BzR). The GABAA receptor is a heteromer composed of five subunits, the most common ones being two αs, two βs, and one γ (α2β2γ1). For each subunit, many subtypes exist (α1–6, β1–3, and γ1–3). GABAA receptors that are made up of different combinations of subunit subtypes have different properties, different distributions in the brain, and different activities relative to pharmacological and clinical effects. Benzodiazepines bind at the interface of the α and γ subunits on the GABAA receptor. Binding also requires that alpha subunits contain a histidine amino acid residue, (i.e., α1, α2, α3, and α5 containing GABAA receptors). For this reason, benzodiazepines show no affinity for GABAA receptors containing α4 and α6 subunits with an arginine instead of a histidine residue. Once bound to the benzodiazepine receptor, the benzodiazepine ligand locks the benzodiazepine receptor into a conformation in which it has a greater affinity for the GABA neurotransmitter. This increases the frequency of the opening of the associated chloride ion channel and hyperpolarizes the membrane of the associated neuron. The inhibitory effect of the available GABA is potentiated, leading to sedative and anxiolytic effects. For instance, those ligands with high activity at the α1 are associated with stronger hypnotic effects, whereas those with higher affinity for GABAA receptors containing α2 and/or α3 subunits have good anti-anxiety activity.

GABAA receptors participate in the regulation of synaptic pruning by prompting microglial spine engulfment. Benzodiazepines have been shown to upregulate microglial spine engulfment and prompt overzealous eradication of synaptic connections. This mechanism may help explain the increased risk of dementia associated with long-term benzodiazepine treatment.

The benzodiazepine class of drugs also interacts with peripheral benzodiazepine receptors. Peripheral benzodiazepine receptors are present in peripheral nervous system tissues, glial cells, and to a lesser extent the central nervous system. These peripheral receptors are not structurally related or coupled to GABAA receptors. They modulate the immune system and are involved in the body's response to injury. Benzodiazepines also function as weak adenosine reuptake inhibitors. It has been suggested that some of their anticonvulsant, anxiolytic, and muscle relaxant effects may be in part mediated by this action. Benzodiazepines have binding sites in the periphery, however their effects on muscle tone is not mediated through these peripheral receptors. The peripheral binding sites for benzodiazepines are present in immune cells and the gastrointestinal tract.

Pharmacokinetics A benzodiazepine can be placed into one of three groups by its elimination half-life, or the time it takes for the body to eliminate half of the dose. Some benzodiazepines have long-acting active metabolites, such as diazepam and chlordiazepoxide, which are metabolised into desmethyldiazepam. Desmethyldiazepam has a half-life of 36–200 hours, and flurazepam, with the main active metabolite of desalkylflurazepam, with a half-life of 40–250 hours. These long-acting metabolites are partial agonists.

• Short-acting compounds have a median half-life of 1–12 hours. They have few residual effects if taken before bedtime, rebound insomnia may occur upon discontinuation, and they might cause daytime withdrawal symptoms such as next day rebound anxiety with prolonged usage. Examples are brotizolam, midazolam, and triazolam.

• Intermediate-acting compounds have a median half-life of 12–40 hours. They may have some residual effects in the first half of the day if used as a hypnotic. Rebound insomnia, however, is more common upon discontinuation of intermediate-acting benzodiazepines than longer-acting benzodiazepines. Examples are alprazolam, estazolam, flunitrazepam, clonazepam, lormetazepam, lorazepam, nitrazepam, and temazepam.

• Long-acting compounds have a half-life of 40–250 hours. They have a risk of accumulation in the elderly and in individuals with severely impaired liver function, but they have a reduced severity of rebound effects and withdrawal. Examples are diazepam, clorazepate, chlordiazepoxide, and flurazepam.

The molecular structure of chlordiazepoxide, the first benzodiazepine. It was marketed by Hoffmann–La Roche from 1960 branded as Librium. The first benzodiazepine, chlordiazepoxide (Librium), was synthesized in 1955 by Leo Sternbach while working at Hoffmann–La Roche on the development of tranquilizers. The pharmacological properties of the compounds prepared initially were disappointing, and Sternbach abandoned the project.

Two years later, on April 1957, co-worker Earl Reeder noticed a "nicely crystalline" compound leftover from the discontinued project while spring-cleaning in the lab. This compound, later named chlordiazepoxide, had not been tested in 1955 because of Sternbach's focus on other issues. Expecting pharmacology results to be negative, and hoping to publish the chemistry-related findings, researchers submitted it for a standard battery of animal tests.

However, the compound showed very strong sedative, anticonvulsant, and muscle relaxant effects. These impressive clinical findings led to its speedy introduction throughout the world in 1960 under the brand name Librium. Following chlordiazepoxide, diazepam marketed by Hoffmann–La Roche under the brand name Valium in 1963, and for a while the two were the most commercially successful drugs. The introduction of benzodiazepines led to a decrease in the prescription of barbiturates, and by the 1970s they had largely replaced the older drugs for sedative and hypnotic uses.