Hypersensitivity phenomena associated with antigen–antibody reactions evoke active release of histamine from the mast cell pool (type I or immediate hypersensitivity). Free histamine then plays an important role in mediating physiological manifestations of such reactions as vasodilation, itching, smooth muscle contraction, and edema. Other autacoids also participate in tissue responses to hypersensitivity reactions. Signs of histamine involvement in systemic anaphylaxis vary in different species. In carnivores, histamine and anaphylaxis produce pronounced hypotension and hepatomegaly. In rabbits, pulmonary arterioles constrict and the right heart dilates in response to either histamine injection or exposure of a sensitized individual to the appropriate antigen. In guinea pigs, dominant manifestations are bronchial constriction and death by asphyxiation. Humans seem to respond like guinea pigs and dogs in that severe hypotension, bronchial constriction, and laryngeal edema are principal signs of anaphylaxis.

The mast cell pool of histamine represents a major target for acute types of hypersensitivity-allergy reactions. As part of the allergic reaction to an antigen, IgE antibodies are generated which bind to the high affinity IgE receptor (FCϵR1) on mast cells. Upon reexposure of the antigen, a crosslinking of two or more IgE molecules induces a signaling cascade involving tyrosine kinases and phosphorylation of several protein substrates within seconds leading eventually to a mobilization of intracellular calcium, which triggers the exocytosis of contents of secretory granules. Recent findings implicate, that the degranulation and secretion of proinflammatory mediators (cytokines/chemokines and leukotrienes) can be regulated by the affinity of the antigen to the specific IgE antibodies bound to the FCϵR1 (Suzuki et al., 2014).

Release is an active process, requiring metabolic energy as well as Ca²⁺, and should be distinguished from simple release secondary to cell destruction and cytolysis.

The ubiquitous cyclic adenosine 3′,5′-monophosphate (cAMP) system is involved in histamine release evoked by antigen–antibody interactions. An increase in cAMP concentration suppresses histamine release (Lichtenstein and Margolis, 1968). Agents that activate adenylyl cyclase (e.g., catecholamines), inhibit phosphodiesterase (e.g., methylxanthines), or activate β₂-adrenergic receptors on mast cells can be anticipated to inhibit the release of histamine. The beneficial effects of drugs widely used in treating allergic disorders, such as the catecholamines, β₂-agonists, and theophylline, may therefore involve inhibition of histamine release in addition to their well-known and more important physiological antagonism of histamine actions on target cells.

Many drugs and chemicals produce direct degranulation of mast cells with release of histamine independently from development of allergy (anaphylactoid reaction). This characteristic action represents an untoward side effect associated either with intravenous (IV) administration of a relatively large dose or direct intradermal injection. Certain chemicals have as their dominant property the ability to release histamine from the mast cell pool.

The curare alkaloids are used clinically as neuromuscular blocking agents (Chapter 10), but they also are notorious for releasing histamine as an adverse side effect; in some species, IV injection of these agents can be followed by histamine-induced bronchospasm and hypotension. Other clinically used drugs that may release histamine include morphine (Guedes et al., 2007), codeine, doxorubicin, vancomycin, and polypeptide antibiotics (polymyxin). However, other opiates such as oxymorphone and hydromorphone are not associated with as much histamine release (Guedes et al., 2006, 2007).

Certain chemicals have been classified simply as histamine-releasing agents because this particular activity supersedes their other pharmacological properties. The best known and most active is the polybasic substance called compound 48/80, a condensation product of p-methoxyphenylethylmethylamine with formaldehyde (Goth and Johnson, 1975). Injection of compound 48/80 or other similar agents evokes classic pharmacological signs of histamine release that are susceptible to blockade by antihistaminic drugs. Tachyphylaxis to repeated injections is characteristic of these chemicals, presumably because of decreased availability of releasable stores of histamine. Endogenous substances that provoke histamine release and may be involved in physiological release mechanisms include bradykinin and stronger histamine releasing substances like kallidin and substance P. Cellular reactions to many venoms (e.g., wasp venom) and toxins also involve histamine release.

When the skin is scratched or pricked, the characteristic redness and urtication that result are due to histamine. This response is quite pronounced in humans. Dermal reactions to severe cold or heat stress likewise depend on histamine liberated by local mast cells. Physical injury of virtually any type sufficiently intense to damage the cells will evoke release of histamine.

The principal circulatory effects of histamine are dilation of terminal arterioles and other vessels of the microcirculation, edema formation caused by increased capillary permeability, and contraction of large arteries and veins. Relative dominance of the actions varies in different species so that net circulatory response to histamine changes as the zoological scale is ascended; for example, arterioles are contracted strongly by histamine in rodents, less so in cats, and actually are dilated in dogs, nonhuman primates, and humans.

In rabbits, histamine is a pressor agent as a result of pronounced constriction of large blood vessels. This constrictor activity is feeble in carnivores where vasodilation of the microcirculation dominates instead. Thus the blood pressure response to histamine in cats, dogs, and primates is hypotension caused by a sharp fall in peripheral vascular resistance. The fall in blood pressure is dose dependent but is usually short lived because of compensatory reflexes and inactivation of histamine.

The striking effects of histamine on the microcirculation can be demonstrated quite convincingly in the human subject. When this agent is administered intradermally, a characteristic triple response is produced, which includes: localized redness at the injection site, developing within a few seconds and attaining maximal hue within a minute; localized edema fluid, forming a wheal in about 90 seconds; and diffuse redness or “flare,” extending about 1 cm from the original red spot. The central redness and edema are from the dilation and increased permeability of local microcirculatory vessels (terminal arterioles, capillaries, and venules). The surrounding flush, which is accompanied by itching and perhaps pain, is due to dilation of neighboring arterioles brought about by a poorly understood axonal reflex mechanism. The triple response of human skin may be similar to manifestations of urticaria in animals. Intradermal injection of histamine leads to a consistent wheal and flare reaction also in dogs. As therapeutically relevant concentrations of cetirizine reduce wheal and erythema by more than 80%, it is likely that these reactions are mainly mediated by activation of H₁ receptor (Bizikova et al., 2008).

Cardiac effects of histamine are minimal when compared to vascular actions. In the intact animal, slight tachycardia is a common finding. This response is mainly secondary to baroreceptor reflexes activated by the depressor effect. In isolated heart muscle, histamine can elicit positive inotropic and chronotropic effects that are produced partly by release of norepinephrine from nerve endings and also to direct activation of H₂ receptors in the heart muscle. There is some evidence that in vivo cardiac responses to histamine injection may partially reflect activation of cardiac H₂ receptors.

Histamine contracts bronchial smooth muscle via H₁ receptors in numerous mammals including the guinea pig, cat, rabbit, dog, goat, calf, pig, horse, and human (Chand and Eyre, 1975; Mohammed et al., 1993; Vietmeier et al., 2007). Guinea pigs are exceptionally sensitive, and even minute doses of histamine can evoke bronchoconstriction leading to death. Humans with bronchial asthma likewise demonstrate increased sensitivity to bronchial effects of histamine and other bronchial smooth muscle stimulants. In contrast, histamine can mediate relaxation of respiratory smooth muscle in some species. Histamine-induced tracheal relaxation in cats involves both H₁ and H₂ receptors, while bronchial relaxation in sheep seems to be mediated by H₂ receptors (Hirschowitz, 1979).

Relaxation of the rat uterus by histamine is mediated by H₂ receptors, but uterine muscle of other species is generally contracted by histamine. Responses of intestinal muscle also vary with species and region, but the classic effect is a contractile response caused by H₁ receptors.

In humans, nonhuman primates, and mice, intradermal injection of histamine induces itch by stimulation C-type nerve fibers (Johanek et al., 2007). Interestingly, dogs show low and very inconsistent itch behavior after intradermal injection of histamine (Carr et al., 2009). In mice and humans it has been shown that both H₁ and H₄ receptor antagonists reduce histamine induced itch, indicating also a central role for H₄R in histamine-dependent pruritus (Kollmeier et al., 2014).

The following exocrine glands are listed in descending order of response to histamine: gastric, salivary, pancreatic, bronchial, and lacrimal. Gastric secretion of hydrochloric acid and, to a lesser degree, pepsinogen is unquestionably the most important; this response is mediated by H₂ receptors.

There is no direct medical use of histamine. It is used as a diagnostic agent to assess bronchial hypersensitivity in humans patients and it is serves as a positive control in humans and dogs during allergy skin testing.