External Three-part body Insects have a
segmented body supported by an
exoskeleton, the hard outer covering made mostly of
chitin. The body is organized into three
interconnected units: the
head,
thorax and
abdomen. The head supports a pair of sensory
antennae, a pair of
compound eyes, zero to three simple eyes (or
ocelli) and three sets of variously modified appendages that form the
mouthparts. The thorax carries the three pairs of legs and up to two pairs of
wings. The abdomen contains most of the digestive, respiratory, excretory and reproductive structures.
Segmentation The head is enclosed in a hard, heavily
sclerotized, unsegmented
head capsule, which contains most of the sensing organs, including the antennae, compound eyes, ocelli, and mouthparts. The thorax is composed of three sections named (from front to back) the
prothorax,
mesothorax and
metathorax. The prothorax carries the first pair of legs. The mesothorax carries the second pair of legs and the front wings. The metathorax carries the third pair of legs and the hind wings. The abdomen is the largest part of the insect, typically with 11–12 segments, and is less strongly sclerotized than the head or thorax. Each segment of the abdomen has sclerotized upper and lower plates (the tergum and sternum), connected to adjacent sclerotized parts by membranes. Each segment carries a pair of
spiracles.
Exoskeleton The outer skeleton, the
cuticle, is made up of two layers: the epicuticle, a thin and waxy water-resistant outer layer without
chitin, and a lower layer, the thick chitinous procuticle. The procuticle has two layers: an outer exocuticle and an inner endocuticle. The tough and flexible endocuticle is built from numerous layers of fibrous chitin and proteins, criss-crossing each other in a sandwich pattern, while the exocuticle is rigid and sclerotized. As an adaptation to life on land, insects have an
enzyme that uses atmospheric oxygen to harden their cuticle, unlike crustaceans which use heavy calcium compounds for the same purpose. This makes the insect exoskeleton a lightweight material.
Internal systems Nervous The
nervous system of an insect consists of a
brain and a
ventral nerve cord. The head capsule is made up of six fused segments, each with either a pair of
ganglia, or a cluster of nerve cells outside of the brain. The first three pairs of ganglia are fused into the brain, while the three following pairs are fused into a structure of three pairs of ganglia under the insect's
esophagus, called the
subesophageal ganglion. The
thoracic segments have one ganglion on each side, connected into a pair per segment. This arrangement is also seen in the first eight segments of the abdomen. Many insects have fewer ganglia than this. Insects are capable of learning.
Digestive An insect uses its digestive system to extract nutrients and other substances from the food it consumes. There is extensive variation among different
orders,
life stages, and even
castes in the digestive system of insects. The
gut runs lengthwise through the body. It has three sections, with paired
salivary glands and salivary reservoirs. By moving its mouthparts the insect mixes its food with saliva. Some insects, like
flies, expel
digestive enzymes onto their food to break it down, but most insects digest their food in the gut. The
foregut is lined with cuticule as protection from tough food. It includes the
mouth, pharynx, and
crop which stores food. Digestion starts in the mouth with enzymes in the saliva. Strong muscles in the pharynx pump fluid into the mouth, lubricating the food, and enabling certain insects to feed on blood or from the
xylem and
phloem transport vessels of plants. Once food leaves the crop, it passes to the
midgut, where the majority of digestion takes place. Microscopic projections,
microvilli, increase the surface area of the wall to absorb nutrients. In the
hindgut, undigested food particles are joined by
uric acid to form fecal pellets; most of the water is absorbed, leaving a dry pellet to be eliminated. Insects may have one to hundreds of
Malpighian tubules. These remove nitrogenous wastes from the hemolymph of the insect and regulate osmotic balance. Wastes and solutes are emptied directly into the alimentary canal, at the junction between the midgut and hindgut.
Reproductive The
reproductive system of female insects consist of a pair of
ovaries, accessory glands, one or more
spermathecae to store sperm, and ducts connecting these parts. The ovaries are made up of a variable number of egg tubes,
ovarioles. Female insects make eggs, receive and store sperm, manipulate sperm from different males, and lay eggs. Accessory glands produce substances to maintain sperm and to protect the eggs. They can produce glue and protective substances for coating eggs, or tough coverings for a batch of eggs called
oothecae. For males, the reproductive system consists of one or two
testes, suspended in the body cavity by
tracheae. The testes contain sperm tubes or follicles in a membranous sac. These connect to a duct that leads to the outside. The terminal portion of the duct may be sclerotized to form the
intromittent organ, the
aedeagus.
Respiratory '' extends horizontally across the body, interlinked with the diamond-shaped
wing muscles (also green) and surrounded by
pericardial cells (red). Blue depicts
cell nuclei.
Insect respiration is accomplished without
lungs. Instead, insects have a system of internal tubes and sacs through which gases either diffuse or are actively pumped, delivering oxygen directly to tissues that need it via their
tracheae and tracheoles. In most insects, air is taken in through paired
spiracles, openings on the sides of the abdomen and thorax. The respiratory system limits the size of insects. As insects get larger,
gas exchange via spiracles becomes less efficient, and thus the heaviest insect currently weighs less than 100 g. However, with increased atmospheric oxygen levels, as were present in the late
Paleozoic, larger insects were possible, such as dragonflies with wingspans of more than . Gas exchange patterns in insects range from continuous and
diffusive ventilation, to
discontinuous.
Circulatory Because oxygen is delivered directly to tissues via tracheoles, the circulatory system is not used to carry oxygen, and is therefore greatly reduced. The insect circulatory system is open; it has no
veins or
arteries, and instead consists of little more than a single, perforated dorsal tube that pulses
peristaltically. This dorsal blood vessel is divided into two sections: the heart and aorta. The dorsal blood vessel circulates the
hemolymph, arthropods' fluid analog of
blood, from the rear of the body cavity forward. Hemolymph is composed of plasma in which
hemocytes are suspended. Nutrients, hormones, wastes, and other substances are transported throughout the insect body in the hemolymph. Hemocytes include many types of cells that are important for immune responses, wound healing, and other functions. Hemolymph pressure may be increased by muscle contractions or by swallowing air into the digestive system to aid in molting.
Sensory s and other sensory organs such as antennae able to detect movements and chemical stimuli on their heads. Many insects possess numerous specialized
sensory organs able to detect stimuli including limb position (
proprioception) by
campaniform sensilla, light,
water, chemicals (senses of
taste and
smell), sound, and heat. Some insects such as
bees can perceive
ultraviolet wavelengths, or detect
polarized light, while the
antennae of male moths can detect the
pheromones of female moths over distances of over a kilometer. There is a trade-off between visual acuity and chemical or tactile acuity, such that most insects with well-developed eyes have reduced or simple antennae, and vice versa. Insects perceive sound by different mechanisms, such as thin vibrating membranes (
tympana). Insects were the earliest organisms to produce and sense sounds. Hearing has evolved independently at least 19 times in different insect groups. Most insects, except some
cave crickets, are able to perceive light and dark. Many have acute vision capable of detecting small and rapid movements. The eyes may include simple eyes or
ocelli as well as larger
compound eyes. Many species can detect light in the
infrared,
ultraviolet and
visible light wavelengths, with color vision. Phylogenetic analysis suggests that UV-green-blue
trichromacy existed from at least the
Devonian Period, some 400 million years ago. The individual lenses in compound eyes are immobile, but fruit flies have photoreceptor cells underneath each lens which move rapidly in and out of focus, in a series of movements called photoreceptor microsaccades. This gives them, and possibly many other insects, a much clearer image of the world than previously assumed. An insect's
sense of smell is via
chemical receptors, usually on the antennae and the mouthparts. These detect both airborne
volatile compounds and odorants on surfaces, including pheromones from other insects and compounds released by food plants. Insects use olfaction to locate mating partners, food, and places to lay eggs, and to avoid predators. It is thus an extremely important sense, enabling insects to discriminate between thousands of volatile compounds. Some insects are capable of
magnetoreception; ants and bees navigate using it both locally (near their nests) and when migrating. The
Brazilian stingless bee detects magnetic fields using the hair-like
sensilla on its antennae. == Reproduction and development ==