Insect Circulatory Systems PDF

Summary

This document provides a detailed explanation of insect circulatory systems. It describes the open circulatory system, featuring hemolymph, the dorsal vessel, and its functions. The document also discusses the composition of hemolymph, including plasma and haemocytes, and their roles in various biological processes.

Full Transcript

Unlike the "closed" circulatory system of humans, insect circulatory
systems are said to be "open", meaning that they lack a complex network
of veins and arteries to help transport blood throughout the body.
Instead, insect blood (called hemolymph) flows relatively "freely"
throughout the hemocoel. Figure 8-2. Circulatory system. Arrows indicate
direction of flow of hemolymph. Only one vessel is present in the insect
circulatory system: the dorsal vessel. Posteriorly (in the abdominal
region), the dorsal vessel acts as the heart, pumping hemolymph forward
into the anterior region (in the head and thorax), where it acts as the
aorta and dumps the hemolymph into the head. It flows posteriorly and is
returned to the heart via ostia, which are small slits in the heart
region of the dorsal vessel designed for hemolymph uptake. To view the
dorsal vessel, examine the "back" (or dorsal region) of the insect's
body cavity for a very thin line that runs longitudinally from the head
to the tip of the abdomen. Use the grasshopper or specimen that was
ventrally dissected, as dorsal dissections will likely mutilate the
vessel. Do not be discouraged if you have trouble finding it on your
specimen. The dorsal vessel is very, very thin. Compare your specimen to
those of your classmates. Circulatory system in insects Aorta portion of
dorsal vessel Heart portion of dorsal vessel Circulation in insects is
maintained by a system of muscular pumps moving haemolymph through
compartments separated by fibromuscular septa or membranes. The main
pump is the pulsatile dorsal vessel. The anterior part may be called
aorta and the posterior part the heart. The dorsal vessel is a simple
tube, generally composed of one layer of myocardial cells and with
segmentally arranged openings called ostia. The ostia permit the one-way
flow of haemolymph into the dorsal vessel due to valves that prevent
backflow. There may be up to three pairs of thoracic ostia and nine
pairs of abdominal ostia. The dorsal vessel lies in the pericardial
sinus, a compartment above a dorsal diaphragm (a fibromuscular septum -
a separating membrane) formed of connective tissue and segmental pairs
of alary muscles. The alary muscles support the dorsal vessel but their
contractions do not affect heartbeat. Haemolymph enters the periocardial
sinus via segmental openings in the diaphragm and then moves into the
dorsal vessel via the ostia during a muscular relaxation phase. Waves of
contraction start at the posterior end of the body, pump the haemolymph
forward in the dorsal vessel and out via the aorta into the head. Next
the appendages of the head and thorax are supplied with haemolymph as it
circulates posteroventrally and finally returns to the pericardial sinus
and dorsal vessel. Another important component of the insect circulatory
system is the ventral diaphragm, a fibromuscular septum that lies in the
floor of the body cavity associated with the ventral nerve cord.
Circulation of the haemolymph is aided by active peristaltic
contractions of the ventral diaphragm which direct the haemolymph
backwards and laterally in the perineural sinus below the diaphragm.
These movements are important in insects that use the circulation in
thermoregulation. Ventral diaphragm also facilitates rapid exchange of
chemicals between the ventral nerve cord and the haemolymph. Haemolymph
is generally circulated to appendages unidirectionaly by various tubes,
septa, valves and pumps. The muscular pumps are termed accessory
pulsatile organs and occur at the base of the antennae and legs.
Antennal pulsatile organs releases neurohormones that are carried to the
antennal lumen to influence the sensory neurones. Circulation occurs in
the wings of young adult. In wing circulation is sustained by influxes
of air into the wing veins, rather than any pulsatile organs. Pulses of
air in the fine tracheal tubes of the veins push the haemolymph through
the enclosed space of the veins. The insect circulatory system shows
high degree of co-ordination between dorsal vessel, fibro-muscular
diaphragms and accessory pumps. Haemolymph and its functions Haemolymph
is a watery fluid containing ions, molecules and cells. It is often
clear and colourless but may be variously pigmented or rarely red due to
haemoglobin in the immature stages of few aquatic and endoparasitic
flies (e.g., Chironomid larva). Haemolymph performs the function of both
blood and lymph. It is not involved in gas transporting function
(respiration). Haemolymph contains a fluid portion called plasma and
cellular fractions called haemocytes. 1.Plasma: Plasma is an aqueous
solution of inorganic ions, lipids, sugars (mainly trehalose), amino
acids, proteins, organic acids and other compounds. pH is usually acidic
(6.7). Density is 1.01 to 1.06. Water content is 84-92 per cent.
Inorganic ions present are \`Na\' in predators and parasites, \`Mg\' and
\`K\'in phytophagous insects. Carbohydrate is in the form of trehalose
sugar. Major proteins are lipoproteins, glycoproteins and enzymes.
Lipids in form of fat particles or lipoproteins. Higher concentration of
amino acids leads to a condition called aminoacidemia which effects the
osmosis process. In high altitude insects glycerol is present which acts
as a anti freezing compound. Nitrogenous waste is present in the form of
uric acid. 2. Haemocytes: The blood cells or haemocytes are of several
types and all are nucleate. Different types of haemocytes are as
follows: a. Prohaemocyte : Smallest of all cells with largest nucleus.
b. Plasmatocyte (Phagocyte) aids in phagocytocis c. Granular heamocyte:
Contains large number of cytoplasmic inclusions d. Spherule cell:
Cytoplasmic inclusions obscure the nucleus e. Cystocyte(Coagulocyte):
Role in blood coagulation and plasma precipitation. f. Oenocytoids:
Large cells with ecentric nucleus g. Adipo haemocytes: Round or avoid
with distinct fat droplets h. Podocyte: Large flattened cells with
number of protoplasmic projections. i. Vermiform cells: Rare type, long
thread like. Functions of haemolymph 1. Lubricant : Haemolymph keeps the
internal cells moist and the movement of internal organs is also made
easy. 2. Hydraulic medium : Hydrostatic pressure developed due to blood
pumping is useful in the following processes. a) Ecdysis (moulting) b)
Wing expansion in adults c) Ecolosion in diptera (adult emergence from
the puparium using ptilinum) d) Eversion of penis in male insects e)
Eversion of osmeteria in papilionid larvae f) Eversion of mask in naiad
of dragonfly g) Maintenance of body shape in soft bodied caterpillars.
3.Transport and storage : Digested nutrients, hormones and gases
(chironomid larva) were transported with the help of haemolymph. It also
removes the waste materials to the excretory organs. Water and raw
materials required for histogenesis is stored in haemolymph.
4.Protection: It helps in phagocytocis, encapsulation, detoxification,
coagulation, and wound healing. Non celluar component like lysozymes
also kill the invading bacteria. 5. Heat transfer: Haemolymph through
its movement in the circulatory system regulate the body heat
(Thermoregulation). 6. Maintenance of osmotic pressure: Ions, amino
acids and organic acids present in the haemolymph helps in maintaining
osmotic pressure required for normal physiological functions. 7. Reflex
bleeding: Exudation of heamolymph through slit, pore etc. repels natural
enemies. e.g. Aphids. 8. Metabolic medium: Haemolymph serves as a medium
for on going metabolic reactions (trahalose is converted into glucose).