2-Anatomy-and-Physioloy-of-Aquatic-Animals.docx

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**Structure and Function - Fish**

**Body**

**External Anatomy of Fishes**

**Anatomy **is the study of an organism's structures. Fishes come in a
diverse array of forms, many with special modifications. The shape,
size, and structure of body parts permit different fishes to live in
different environments or in different parts of the same environment.
The external anatomy of a fish can reveal a great deal about where and
how it lives.

**Body Form**

Perches are the most common type of bony fishes. As a result, people
often use the words *perch-like* to describe a generic fish shape. (Fig.
4.21 A). Fusiform is the scientific term used to describe the perch's
streamlined, torpedo shaped body. **Compressiform **means laterally
flattened (Fig. 4.21 B). **Depressiform **means dorso-ventrally
flattened (Fig. 4.21 C). **Anguilliform **means eel-like (Fig. 4.21 D).
See Table 4.4 for additional descriptions of fish body shapes.

\\Fig. 4.21.\ (\A\) Perch
(fusiform-torpedo shape)\![\\Fig.
4.21. \(B) Angelfish (compressiform-flat side to
side)\ ](media/image2.jpeg)

**Fig. 4.21.** (**A**) Perch (fusiform-torpedo shape) **Fig. 4.21. **(B)
Angelfish (compressiform-

Image: U.S. Department of Agriculture flat side to side)

\\Fig. 4.21.\ (\C\) Flounder
(depressiform-flat top to bottom)\ ![\\Fig.
4.21.\ (\D\) Eel (anguiliform-eel
like)\ ](media/image4.jpeg)

**Fig. 4.21.** (**C**) Flounder (depressiform-flat **Fig.
4.21.** (**D**) Eel (anguiliform-eel

top to bottom) like)

Image: Katie Samuelson Image: Wikimedia Commons

**Table 4.4. **Fish form and function: body shape

**Diagram of Body** **Description** **Adapted Function**
------------------------- -------------------------------------------------------------------------------- --------------------------------------------------------------
Anguiliform (eel shape) Maneuvering in crevasses
 Fusiform (bullet, or torpedo shape) Lowering frictional resistance in fast swimmers
Depressiform (broad shape and flat top to bottom) Lying on or below the surface of the sand
 Compressiform (tall, thin shape and flat side to side) Entering vertical crevices
Vertically flattened shape that is somewhat depressiform (flat top to bottom) Bottom heavy for sitting on the bottom, not casting a shadow
 Fusiform (bullet, or torpedo shape), which is also sometimes called perch like General all-purpose shape
Elongated shape that is somewhat anguiliform (eel shape) Ambush predators

**Fish Fins**

 The first anatomical structures many people identify on a fish are the
fins. In fact, "appendages, when present, as fins" is part of one of the
scientific definitions of a fish. Most fish have two kinds of fins:
median and paired.

**Median fins** are single fins that run down the midline of the body.
The dorsal fin is a median fin located on the dorsal side of the fish.
The anal fin and caudal fin are also median fins. **Paired fins** are
arranged in pairs, like human arms and legs. The pelvic and pectoral
fins are both paired fins. (Table 4.5).

![\\Fig. 4.9.\ (\B\)
Anatomy of a soldierfish, \Myripristis
\\berndti\\](media/image12.png)

**Fig. 4.9.** (**B**) Anatomy of a soldierfish, *Myripristis berndti*

Image by Byron Inouye

**Table 4.5. **Fish form and function: dorsal fin features

**DORSAL FIN DIAGRAM** **DESCRIPTION** **ADAPTED FUNCTION**
------------------------- ---------------------------------- -------------------------------------
Spiny and soft-rayed dorsal fin. Flared to make the fish look bigger
 Tucked dorsal fin Reduces drag in fast swimming fish
Locking spiny dorsal fin Locking fish into coral crevices
 Very long dorsal fin Snake-like locomotion
Three dorsal fins Locomotion
 No dorsal fin Snake-like locomotion

**Median Fins**

Median fins, like the dorsal, anal, and caudal fins, can function like
the keel of a boat and aid in stabilization (Fig. 4.22 A). Median fins
can also serve other purposes, like protection in the lion fish (Fig.
4.22 B).

\\Fig. 4.22. (A)\ The keel of boat stabilizes the
boat, similar to a fish's anal fin\ ![\\Fig.
4.22\\.(\\B)\ The dorsal
fin of a lionfish has spines and poison for protection\
](media/image20.jpeg)

**Fig. 4.22. (A)** The keel of boat stabilizes **Fig. 4.22.(B)** The
dorsal fin of a lionfish

the boat, similar to a fish's anal fin has spines and poison for
protection

Image: Brother Magneto Flickr Image: Katie Samuelson

**Caudal (Tail) Fin**

The **caudal fin** is known commonly as the tail fin (Table 4.6). It is
the primary appendage used for locomotion in many fishes. The caudal fin
is also a median fin (Fig. 4.22 A).

The **caudal peduncle** is the base of the caudal fin. Peduncle means
stem, and the caudal peduncle is where the strong swimming muscles of
the tail are found. Together, the caudal fin acts like a "propeller" for
the fish, and the caudal peduncle acts like a motor.

**Table 4.6. **Fish form and function: Caudal fin features

**Tail Diagram** **Description** **Adapted Function**
------------------------ -------------------------------------- ---------------------------------------------------------
Rounded tail Slow swimming, accelerating, and maneuvering
 Truncated (triangular) tail Turning quickly
Lunate (moon shaped) tail Continuous long distance swimming
 Forked tail Rapid swimming, somewhat sustained with bursts of speed
Heteroceral (taller upper lobe) tail Slow or rapid swimming with bursts of speed

![\\Fig. 4.25. (A)\ trout showing two dorsal fins
on top and, from left to right, pectoral, pelvic, and anal fins\
](media/image26.jpeg)\\Fig 4.25. (B)\
wrasse\

**Fig. 4.25. (A)** trout showing two dorsal fins on top **Fig 4.25.
(B)** wrasse

and, from left to right, pectoral, pelvic, and anal fins Photo courtesy
of Katie Samuelson

Photo courtesy of the Wild
Center [[Flickr]](http://www.flickr.com/photos/thewildcenter/6966690766/in/photostream/)

**Paired Fins**

Fish have two sets of paired fins: pectoral and pelvic (Fig 4.25).
The **pectoral fins** are vertical and are located on the sides of the
fish, usually just past the operculum (Table 4.7). Pectoral fins are
similar to human arms, which are found near the pectoral muscles. Many
fish, such as reef fish like wrasses (Fig. 4.25 B), use their pectoral
fins for locomotion.

**Table 4.7.** Fish form and function: Pectoral fin features

**Pectoral Fin Diagram** **Description** **Adapted Function**
-------------------------- --------------------------- -----------------------
 Fringe-like pectoral fins Probing substrate
Spiny pectoral fins Propping on substrate
 Hand-like pectoral fins Crawling on substrate
Wing-like pectoral fins Soaring and swimming
 No pectoral fins Snake-like swimming
Normal size pectoral fins Maneuvering

The **pelvic fins** sit horizontally on the ventral side of the fish,
past the pectoral fins (Table 4.8). Pelvic fins are similar to legs.
Just like human legs, pelvic fins are associated with the pelvis of the
fish.

**Table 4.8.** Fish form and function: Pelvic Fin Features

**Pelvic Fin Diagram** **Description** **Adapted Function**
------------------------- ------------------------------- ----------------------------
 Sucker-like pelvic fins Grabbing rocks by sucktion
Thickened rays on pelvic fins Sitting on substrate
 Moderate sized pelvic fins Locomotion

**Unique and Specialized Fins**

Paired fins are most commonly used for maneuvering, like the oars on a
rowboat. However, both the pectoral and pelvic fins can also be highly
specialized like those of the flying fish (Fig. 4.26 A). Unique
combinations of other fins can also help fish to be even more
specialized, like the pectoral and anal fins of a box fish (Fig. 4.26 B;
see Table 4.9).

\\Fig. 4.26. (A)\ Flying fish with highly
specialized pectoral and pelvic fins for flying\
![\\Fig. 4.26 (B)\ Spotted boxfish with
specialized dorsal and anal fins for moving its boxy body\
](media/image38.jpeg)

**Fig. 4.26. (A)** Flying fish with **Fig. 4.26 (B)** Spotted boxfish
with specialized

highly specialized pectoral and dorsal and anal fins for moving its boxy
body

pelvic fins for flying Image courtesy of Katie Samuelson

Image: Theron
Trowbridge [[Flickr]](http://www.flickr.com/photos/therontrowbridge/8152593248/)

**Table 4.9**. Fish form and function: Combinations of Fins

**Fin Combination Diagram** **Description** **Adapted function**
----------------------------- ------------------------ ---------------------------------
Dorsal and anal fins Modified to increase propulsion
 Pectoral and tail fins Modified for soaring in air

**Spines and Rays**

Scientists use fins to help identify and classify fish species. In more
evolutionarily advanced fish, the fins are supported by bony structures:
spines and soft rays. **Spines** are simple, unbranched,
structures. **Soft rays** are compound, segmented, and branched
structures (Fig. 4.27).

\\Fig. 4.27. (A)\ The elongated dorsal fin of a
common carp, with 1 spine and 15-22 soft rays.\
![\\(B)\ A dorsal fin drawing of a soldierfish's
second dorsal fin, showing fin spines (unbranched) and rays (branched
and softer than spines).\ ](media/image42.jpeg)

**Fig. 4.27. (A)** The elongated dorsal fin of a **(B)** A dorsal fin
drawing of a soldierfish's

common carp, with 1 spine and 15-22 soft rays. second dorsal fin,
showing fin spines

Image courtesy of John Lyons, University of (unbranched) and rays
(branched

Wisconsin Sea Grant  and softer than spines).

**The Mouth**

The mouth is at the front, or anterior end, of the fish. The mouth can
reveal a lot about the fish's feeding habits (Table 4.10). The size,
shape, and placement of the mouth, combined with the type of teeth,
provide critical information about the feeding habits of a fish (Table
4.11).

For example, a fish with a mouth on the bottom of its head often feeds
by digging in the bottom sediment (Fig. 4.28 A). A fish with a mouth
oriented upward usually feeds in the water column, or even above the
water (Fig. 4.28 B). When a fish has its mouth open, the front lip may
slide down and out from the mouth. This sliding action of the mouth can
help the fish create a vacuum and quickly suck in a big mouthful of
water, which hopefully also includes prey!

 Sturgeon Teeth: Everything You Need To Know - AZ Animals ![Arowana
Care: Compelete Guide On Types, Tank Size, Diet &
More](media/image44.jpeg)

**Fig. 4.28. (A)** A bottom facing mouth **(B)** An upward facing mouth
shows

indicates bottom feeding preferences the surface feeding adaptation of

in the sturgeon.** ** the arowana.

**Table 4.10.** Fish form and function: Mouth Features

**Mouth Diagram** **Description** **Adapted Function**
------------------------- -------------------- ----------------------------------
Jawless Scavenging or parasitic behavior
 Tweezer-like snout Poking into crevices
Suction tube Slurping in prey
 Large mouth Swallowing large prey
Beak-like teeth Biting hard objects
 Tiny and turned up Capturing plankton

**Table 4.11.** Fish form and function: Teeth Features

**Teeth Diagram** **Description** **Adapted Function**
------------------------- ---------------------------- -----------------------------------
Pointed Stabbing
 Comb-like Scraping material off rocks
Heavy and flat, molar like Grinding
 Fused like a beak  Scraping hard materials off rocks
Incisor-like Cutting
 Broom-like  Filtering

**Eyes**

The eyes of fish resemble human eyes (Fig. 4.29). At the front of each
eye is a lens, held in place by a suspensory ligament.
The **lens** focuses images of objects on the retina. To bring near and
far objects into focus, the lens retractor muscle moves the lens back
and forth.

\\Fig. 4.29\ Eye of a bigeyed sixgill shark
(Hexanchus nakamurai)\

**Fig. 4.29** Eye of a bigeyed sixgill shark (Hexanchus nakamurai)

[[https://en.wikipedia.org/wiki/File:Hexanchus\_nakamurai\_JNC2615\_Eye.JPG]](https://en.wikipedia.org/wiki/File:Hexanchus_nakamurai_JNC2615_Eye.JPG%20Images%20courtesy%20of%20Jean-Lou%20Justine)\
Images courtesy of Jean-Lou Justine

The **retina** is a light-sensitive membrane rich in nerves that connect
to the optic lobes of the brain by optic nerves. When light shines on
the nerves of the retina, the **optic nerves** send impulses to the
optic lobes. Because fish have no eyelids, their eyes are always open.

Some elasmobranchs, and most teleost fishes, have color vision. Some
fishes can also see in ultraviolet (UV) light. UV vision is especially
useful for reef fishes. UV vision helps fishes in foraging,
communication, and mate selection.

Elasmobranchs, and some teleosts, also have a tapetum lucidum. The
tapetum lucidum is a shiny, reflective structure that reflects light and
helps vision in low light situations. The **tapetum lucidum** is what
makes the eyes of sharks and deep sea fish, as well as land mammals like
cats and cows, shine at night.

Fish eyes are usually placed just dorsal of and above the mouth. Just
like the mouth of a fish, the size, shape, and position of the eyes can
provide information about where a fish lives and what it feeds on. For
example, fish predators often have eyes facing forward in order to
provide better depth perception. Prey fish, on the other hand, often
have eyes on the sides of their bodies. This gives them a larger field
of view for avoiding predators. (Table 4.12).

**Table 4.12. **Fish form and function: Eye Features

**Eye Diagram** **Description** **Adapted Function**
------------------------- ------------------------------------------------------------------------- -----------------------------------------------------
 Tiny eyes, head length approximately six times longer than eye width Receiving high intensity light
Large eyes, head length approximately three times longer than eye width Receiving low intensity light or spotting predators
 Average eyes head length three to five times longer than eye width Receiving normal intensity light
Tubular eyes Receiving low light from above often in deep water
 Eyes on dorsal side of the fish Seeing above

**Nostrils**

The sense of smell is well developed in some fishes. Water circulates
through openings in the head called **nostrils**. Unlike humans, fish
nostrils are not connected to any air passages. Fish nostrils serve no
role in respiration. They are completely sensory.

The largest part of a fish's brain is the olfactory lobe, which is
responsible for the sense of smell. Smell is the response to chemical
molecules by nerve endings in the nostrils. **Chemoreception** is the
scientific term for what nerve cells do to help an organism smell (see
Table 4.13).

**Taste Receptors**

Taste is another form of chemoreception. Fish can taste inside their
mouth. Many fishes, like goatfish and catfish, also have fleshy
structures called **barbels** around the chin, mouth, and nostrils (see
Table 4.13 and Fig. 4.30). In some fishes, these barbels are used for
touch and chemoreception.

\\Fig 4.30.(A) \Goatfish with chemosensory
barbels that can taste and smell\![\\(B)\
Catfish with non-chemosensory barbels, which cannot taste or
smell\](media/image64.jpeg)\\(C)\ Blenny
with non-chemosensory cirri, which cannot taste or smell\

**Fig. 4.30. (A) **Goatfish with Figure 4.30. (B) Catfish with non-
**Fig 4.30. (C)** Blenny with

chemosensory barbels that can chemosensory barbels, which
non-chemosensory cirri,

taste and smell cannot taste or smell which cannot taste or Image: Katie
Samuelson Photo courtesy of Pil  smell

Image: Katie Samuelson

Not all barbels have chemoreception. The barbels of some fish, like
catfishes, are not equipped for chemical reception (Fig. 4.30 B). Some
fish also have fleshy tabs called cirri on the head (Fig. 4.30 C). Cirri
are not sensory organs.

**Table 4.13.** Fish form and function: Chemosensory Adaptation and
Camouflage

**Diagram** **Description** **Adapted function**
------------------------- ----------------------- ---------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 Barbels Probing for food in sand. Can detect chemicals for smelling and tasting (but note that not all fishes' barbels can detect chemicals---like catfish barbels are cannot taste or smell)
Tubular nostrils Detecting chemicals for smelling and tasting
 Cirri on head by eyes Camouflage (although they resemble chemosensory organs, they do not respond to chemicals)

Image: Byroun Inouye and DiscoverLife.org

**Lateral line**\
Most fish have a structure called the lateral line that runs the length
of the body---from just behind the head to the caudal peduncle (Fig.
4.31). The **lateral line** is used to help fishes sense vibrations in
the water. Vibrations can come from prey, predators, other fishes in a
school, or environmental obstacles.

\(A) Location of the lateral line on a shark\
![\\(B)\ Location of the lateral line on a fish
and englarged view of a lateral line, showing the lateral line tube
reaching through pores in the fish scales\ ](media/image70.jpeg)

Figure 4.31 (A) Location of the lateral Figure 4.31 (B) Location of the
lateral line

line on a shark on a fish and enlarged view of a lateral line

Image courtesy of Byron Inouye showing the lateral line tube reaching
through pores in the fish scales

Image from Living Ocean

The lateral line is actually a row of small pits that contain special
sensory hair cells (Fig. 4.32). These hair cells move in response to
motion near the fish. The lateral line sense is useful in hunting prey,
escaping predators, and schooling.

\Lateral line, close-up of pits with hair cells\

Fig. 4.32 Lateral line, close-up of pits with hair cells

Image courtesy of Thomas Haslwanter, Wikimedia
Commons 

**Ampullary receptors**
-----------------------

**Ampullary receptors** are sense organs made of jelly-filled pores that
detect electricity. They can detect low frequency alternating current
(AC) and direct current (DC). Ampullae detect electricity emitted by
prey as well as the small electrical fields generated by a fish's own
movement through the earth's magnetic fields. Researchers think that
this may help fishes use the Earth's magnetic field for navigation.
Fishes that have ampullae include sharks, sturgeon, lungfish, and
elephant fish. The ampullae of sharks are known as Ampullae of
Lorenzini---named for Stefano Lorenzini, who first described them in
1678 (Fig. 4.33).

![\\Fig 4.33.(A)\ Ampullae of Lorenzini in a
shark's head\](media/image72.png)\\(B)\
Ampullae of Lorenzini pores on the snout of a tiger shark\

Fig 4.33 **(A)** Ampullae of Lorenzini in a shark's head Fig 4.33
**(B)** Ampullae of Lorenzini pores

Image courtesy of Chris Huh  on the snout of a tiger shark

Some fishes can also generate their own electrical fields. These fishes
have both ampullae type receptors and tuberous type receptors. The
tuberous receptors are most sensitive to the electric organ discharge of
the fish itself, which is important for object detection. The tuberous
type of receptor is usually deeper in the skin than ampullae.

Some fishes that produce electricity also use it for communication.
Electric fishes communicate by generating an electric field that another
fish can detect. For example, elephant fishes use electrical
communication for identification, warning, submission, courtship, and
schooling (Fig. 4.34).

![\\Fig 4.34 \The elephant fish use electric
impulses to communicate.\ ](media/image74.jpeg)

**Fig 4.34 **The elephant fish use electric impulses to communicate.

**Image:** [Wikipedia](https://commons.wikimedia.org/wiki/File:Elef.jpg)

**Ears**
--------

Sound travels well underwater, and hearing is important to most fishes.
Fishes have two inner ears embedded in spaces in their skulls. The lower
chambers, the sacculus and the lagena, detect sound vibrations. (See
Fig. 4.35.)

\\Fig 4.35.\ Inner ear of a fish\

**Fig 4.35.** Inner ear of a fish

Image from Living Ocean

Each ear chamber contains an otolith and is lined with sensory
hairs. **Otoliths** are small, stone-like bones (See Fig. 4.36). They
float in the fluid that fills the ear chambers. Otoliths lightly touch
the sensory hair cells, which are sensitive to sound and movement.

![\\Fig. 4.36. (A) \Otolith (ear bone) of an
American barrelfishImage courtesy of NOAA Ocean Explorer\
](media/image76.jpeg)\\Fig. 4.36. (B)\ A pair of
otoliths from a 160lb eight-banded grouper\

**Fig. 4.36. (A) **Otolith (ear bone) of an **Fig. 4.36. (B)** A pair of
otoliths from a

American barrelfish 160lb eight-banded grouper

Image courtesy of NOAA Ocean Explorer Image by Kanesa Duncan Seraphin

Like the otoliths in human ears, otoliths in fishes help with hearing
and with balance. When a fish changes position, the otoliths bump the
hair cells in the ampullae. The ampullae are bulges in
the **semicircular canals** of the ears (Fig 4.36). When a fish rolls
right or left, tail up or tail down, the liquids and otoliths push
against the hairlike nerve endings lining the canal, sending messages to
the fish's brain.

Some fishes also use other organs to aid in hearing. For example, the
gas bladder changes volume in response to sound waves. Some fishes can
detect these changes in gas bladder volume and use them to interpret
sounds.

**Gills and Oxygen Exchange**
-----------------------------

Most mammals get oxygen from the air, but most fishes get oxygen from
the water. To get oxygen from the water, fish must pass water over their
gills. Gills are composed of a gill arch, gill filaments, and gill
rakers (see Fig. 4.37). In many fishes the gill arch is a hard structure
that supports the gill filaments. The gill filaments are soft with lots
of blood vessels to absorb oxygen from the water.

![\\Fig. 4.37. (A)\ A bony fish with the
operculum held open to show the
gills\](media/image78.jpeg)\\(B)\ A single
gill removed from a bony fish\![\\(C)\ A
drawing of a gill showing gill filaments (oxygen absorption), gill arch
(supporting structure), and gill rakers (comb like structure for
filtering)\](media/image80.jpeg)

**Fig. 4.37. (A)** A bony fish with **(B)** A single gill removed
**(C)** A drawing of a gill showing

As water passes through a fish's mouth, over the gills, and back into
the environment, oxygen and carbon dioxide are exchanged. Some fishes,
like tunas, need to continuously swim to get oxygen from the water.
Other fishes, like wrasses, can pass water over their gills by pumping
it. This enables wrasses to remain motionless and still get oxygen.

Fishes get both oxygen and food from water. To get oxygen, water needs
to move toward the gills. But, to get energy from food, the food needs
to move down into the fish's stomach. The **gill rakers** are comb-like
structures that filter food from the water before it heads to the gills.
This keeps food particles inside the fish's mouth and lets water move
out toward the gills.

The structure of a fish's gill rakers indicates something about its
diet. Fish that eat small prey like plankton tend to have many long,
thin gill rakers to filter very small prey from the water as it passes
from the mouth to the gills. On the other hand, fish that eat large prey
tend to have more widely spaced gill rakers, because the gill rakers do
not need to catch tiny particles.

The **Operculum** is the bony plate that covers fishes' gills. In
chimeras and bony fishes, the operculum covers the posterior end of the
head, which protects the gill openings. The bony operculum often has
another bony flap, called the **preoperculum**, overlaying it (Fig.
4.30). Some fishes also have a strong spine, or spines, that project
back from the preoperculum or operculum. These spines are usually used
for protection.

Sharks and rays have open, naked gills (see Table 4.14), meaning that
they are not covered by an operculum. Their classification
name, **elasmobranch**, actually means naked gill. Most elasmobranchs
have five gill openings---exceptions include the six gill and seven gill
shark.

**Table 4.14.** Fish form and function: Gills

**GILL DIAGRAM** **DESCRIPTION** **ADAPTED FUNCTION**
------------------------- ----------------------------------- ----------------------
Elasmobranchs have naked gills Easy water flow
 Operculum covers gills Gill protection
Preoperculum and operculum spines Armor and protection

![\\Fig. 4.38. (A)\ A semicircle angelfish
(Pomacanthus semicirculatus) with bright blue highlight color on the
preoperculum, preoperculum spine, and operculum\
](media/image84.jpeg)\\(B)\ A dog snapper
(Neomaenis jocu) with preoperculum, operculum, and operculum spine
labeled.\

**Fig. 4.38. (A)** A semicircle angelfish **(B)** A dog snapper
(Neomaenis jocu) with

(Pomacanthus semicirculatus) with bright with preoperculum, operculum,
and

blue highlight color on the preoperculum, operculum spine labeled.

preoperculum spine, and operculum Image by Byron Inouye

Image by [Stan
Shebs](https://commons.wikimedia.org/wiki/File:Pomacanthus_semicirculatus_1.jpg)

The **buccal pump** is what fish use to move water over their gills when
they are not swimming. The buccal pump has two parts: the mouth and the
operculum. During the first stage of pumping, both opercula close, and
the mouth opens. Water then enters through the mouth. Next, the fish
closes its mouth and opens its opercula so that water moves over the
gills, which remove oxygen from the water. Some fishes also use the
buccal pump as part of their feeding strategy by filtering out small
organisms living in the water as they pump water (Fig. 4.39). As water
passes through, the gill rakers help to trap plankton from the water.

![\\Fig. 4.39.\ Some fishes feed by filtering out
through their buccal pump such as this whale shark, which feeds on
plankton\ ](media/image86.jpeg)

**Fig. 4.39.** Some fishes feed by filtering out through their buccal
pump such as this whale shark, which feeds on plankton

Image by Arturo de Frias Marques

**Pores**
---------

A **pore** is a small opening in the skin. A typical fish has anal,
genital, and urinary pores located anterior of the anal fin. The **anal
pore** is where feces exits the fish body. The anus is the largest and
most anterior of the pores (Fig. 4.40 A).

The **genital pore** is where eggs or sperm are released. The **urinary
pore** is where urine exits the body. Often the genital and urinary pore
are combined into a single **urogenital** pore. These pores are situated
on a small papilla, or bump, just behind the anus (Fig. 4.40 B). 

\\Fig. 4.40.\ Anal pore (toward the head) and
genital and/or urinary pores (toward the tail)\

**Fig. 4.40.** Anal pore (toward the head) and genital and/or urinary
pores (toward the tail)

Image
from 

Most fishes reproduce externally, meaning that the sperm and eggs meet
outside their bodies. However, some fishes reproduce internally. The
females of these fishes often have a genital pore that is modified for
internal fertilization.

**Body Coverings**
------------------

One definition of a fish includes "body usually covered with scales."
Except for some parts of the head and fins, the bodies of many fishes
are covered with overlapping scales (Fig. 4.41). **Scales** generally
serve to protect the fish's skin.

![\\Fig. 4.41.\ The overlapping scales of a roach
fish (Rutilus rutilus)\ ](media/image88.jpeg)

**Fig. 4.41.** The overlapping scales of a roach fish (Rutilus rutilus)

Image
by [kallerna](https://en.wikipedia.org/wiki/File:Scale_Common_Roach.JPG)

Different fishes have different types of scales. These different types
of scales are made of different types of tissue (Fig. 4.42 and Table
4.15). Types of scales also correspond to evolutionary relationships
(Fig. 4.9).

**Placoid scales** are found in the sharks and rays (Fig. 4.42 A).
Placoid scales are made of a flattened base with a spine protruding
towards the rear of the fish. These scales are often called dermal
denticles because they are made from dentin and enamel, which is similar
to the material teeth are made of.

**Ganoid scales** are flat and do not overlap very much on the body of
the fish (Fig. 4.42 B). They are found on gars and paddlefishes. In the
sturgeon, ganoid scales are modified into body plates called scutes.

**Cycloid and Ctenoid scales** are found in the vast majority of bony
fishes (Figs 4.42 C and 4.42 D). These types of scales can overlap like
shingles on a roof, which gives more flexibility to the fish. These
scales also form growth rings like trees that can be used for
determining age.

Ctenoid scales are different than cycloid scales in that cycloid scales
tend to be more oval in shape. Ctenoid scales are more clam shaped and
have spines over one edge. Cycloid scales are found on fishes such as
eels, goldfish, and trout. Ctenoid scales are found on fishes like
perches, wrasses, and parrotfish. Some flatfishes, like flounder, have
both cycloid and ctenoid scales.

\\Fig. 4.42.\ Four types of fish scales A)
Placoid, B) Ganoid, C) Cycloid, and D) Ctenoid\

**Fig. 4.42.** Four types of fish scales A) Placoid, B) Ganoid, C)
Cycloid, and D) Ctenoid

Image from Living Ocean, CRDG, University of Hawaii at Manoa

**Table 4.15.** Fish form and function: Scale Features

**Scale Diagram** **Description** **Adapted Function**
------------------------- ----------------------------- ---------------------------------------------------
 Spines Protection from predators
Blades Protection and defense
 Scutes (or keel; not shown) Cuts through water, streamlines swimming
Many large scales Protection
 No scales Burrowing
Leathery scales Protection
 Bony armor scutes Protection from predators
Rough scales Protection from parasites and swimming locomotion
 Regular scales Protection

\\Fig. 4.43. (A) \Pinecone fish\
![\\(B)\ porcupine fish\
](media/image100.jpeg)

**Fig. 4.43. (A) **Pinecone fish **(B)** porcupine fish

Photo courtesy of Spencer77  Photo courtesy of Katie Samuelson

 Scale size varies greatly among species, and not all fishes have
scales. Some fishes, like some rays, eels, and blennies, do not have any
scales. This is probably because these fishes spend a lot of time
rubbing on the sand or in rocks. If they had scales, the scales would
likely rub off. At the other extreme, some fishes have scales modified
into bony plates, such as on a sturgeon and pinecone fish (Fig. 4.43 A).
Other fish have scales modified into spines for protection, like the
porcupine fish (Fig. 4.43 B).

Additional Modifications
------------------------

Fishes are very diverse, and there are examples of extreme body
modifications in many different groups of fishes (see Table 4.16). For
example, some fishes, like angler fish, have lures to attract prey.
Others, like lionfish, have poison sacs to protect them from predators.

**Table 4.16.** Fish form and function: Other Modifications

**Diagram** **Description** **Adapted Function**
-------------------------- ------------------------------- ----------------------
Lures Attracting prey
 Poison sacs at base of spines Protection

**Color**\
The color of fishes is very diverse and depends on where a fish lives.
Color can be used as camouflage. Color also plays a role in finding
mates, in advertising services like cleaning, in attracting prey, and in
warning other fishes of danger (see Table 4.17).

Tunas, barracuda, sharks, and other fishes that live in the open ocean
are often silvery or deep blue in color. These fishes also have a body
coloring pattern called counter shading. Counter shading means dark on
the dorsal, or top, surface and light on the ventral, or belly
side. **Countershading** helps to camouflage fishes by matching the
dark, deep water when viewed from above and matching the light, surface
water, when viewed from below (Fig. 4.44 B).

\\Fig. 4.44. (A)\ blue silvery color in Heller's
barracuda\ ![\\(B) \Countershading in a grey
reef shark\ ](media/image104.jpeg)

**Fig. 4.44. (A)** blue silvery color in Heller's barracuda
**(B) **Countershading in a grey reef shark

Image courtesy of Katie Samuelson Image courtesy
of [Fbattail](https://commons.wikimedia.org/wiki/File:Tibur%C3%B3n.jpg)

Nearer to shore, many fishes have also evolved to be camouflaged in
their environment. Kelpfish have developed both colors and a body shape
that helps them blend in with the seaweed that they live in. Reef fish
often look like coral. Fishes that hide in the sand, like blennies, flat
fish, and flounder, are often a speckled sandy color (Fig. 4.45 B).

\\Fig. 4.45. (A)\ A leafy seadragon hiding in
kelp\ ![\\(B)\ A blenny hiding in
coral\](media/image106.jpeg) \\(C)\ A
three-spot flounder hiding in sand(C) A three-spot flounder hiding in
sand\

**Fig. 4.45. (A)** A leafy seadragon **(B)** A blenny hiding in coral
**(C)** A three-spot flounder hiding in

hiding in kelp Image courtesy of [Jason
Marks](https://en.wikipedia.org/wiki/File:Salarias_sinuosus_(Fringelip_blenny).jpg)
sand

Image courtesy
of [EyeKarma](https://en.wikipedia.org/wiki/File:Leafyseadragon2276ppx_PLW_edit.JPG)
Image: Katie Samuelson

Many brightly colored fishes that live in coral reef habitats also use
their color, stripes, and spots as camouflage (Fig. 4.46). This is
partly because wavelengths of light, and therefore color, appear
different under water and change with depth and water color. Water
absorbs light. Thus, the amount of light decreases with increasing
depth.

Red color, for example, fades out very fast with increasing depth.
Fishes with red color, like soldierfish (Fig. 4.46 A), are actually
invisible at night and in deep waters. Yellow and blue colors, on the
other hand, blend in with the reef color, also providing camouflage from
predators (Fig. 4.46 B). Even stripes and spots can prevent an
individual fish from standing out, making it harder for a predator to
strike (Fig. 4.46 C).

![\\Fig. 4.46. (A)
\Soldierfish\](media/image108.jpeg)\\(B)\
blue and yellow Hawaiian cleaner
wrasse\![\\(C)\ school of convict tang and
whitebar surgeonfish\](media/image110.jpeg)

**Fig. 4.46. (A) **Soldierfish **(B)** blue and yellow Hawaiian
**(C)** school of convict tang

Image: Katie Samuelson cleaner wrasse and whitebar surgeon fish Image:
Katie Samuelson Image: Katie Samuelson

In addition to colors visible to humans, fish also use ultraviolet (UV)
light colors for camouflage and communication. Some fishes can see using
UV light, and so they use UV colors to identify each other and to avoid
predators. Many reef fish can also blink their colors on and off to
flash messages (Fig. 4.47). Skin cells called chromatophores allow fish
and other animals to quickly change skin color.

\\Fig. 4.47.\ Examples of color-changing fish.
The peacock flounder (Bothus mancus or pāki'i in Hawaiian) is a
bottom-dwelling flatfish common in the tropical Pacific. It can rapidly
change skin colors.\

**Fig. 4.47.** Examples of color-changing fish. The peacock flounder
(Bothus mancus or pāki'i in Hawaiian) is a bottom-dwelling flatfish
common in the tropical Pacific. It can rapidly change skin colors.

Image courtesy of [Brocken
Inaglory](https://commons.wikimedia.org/wiki/File:Peacock_Flounder_Bothus_mancus_in_Kona.jpg),
Wikimedia Commons

**Table 4.17**

**Body Color Diagram Example** **Picture Example** **Description** **Adapted Function**
-------------------------------- --------------------- ---------------------------------------------------------------------------------------------------- ---------------------------------
 Both sexes brightly colored A warning---not good to eat
 Brightly colored areas around the spine on the caudal peduncle area. The spine is used in defense. Warning
 Mottled Camouflage
 Dark on top, lighter on bottom Camouflage in midwater
 Dark all over Camouflage in dark areas
 Red all over Camouflage in dark areas
 Light all over Camouflage in light areas
 Eyespots Leading predator away from head
 Brightly colored Camouflage or communication

Internal Fish Anatomy and the Function of Fish Organ Systems
------------------------------------------------------------

Living things are composed of cells. Cells often become specialized to
perform certain functions. For example, muscle cells contract, nerve
cells transmit impulses, and gland cells produce chemicals. A tissue is
a group of similar cells performing a similar function (Fig. 4.48).
There are many kinds of tissues---bone, cartilage, blood, fat, tendon,
skin, and scales.

![\\Fig. 4.48.\ Organization of structures in
living organisms\ ](media/image130.jpeg)

**Fig. 4.48.** Organization of structures in living organisms

Image from Living Ocean, CRDG, University of Hawaii at Manoa

Integumentary System
--------------------

The** integumentary system** is commonly called the skin. It consists of
two layers, the epidermis, or outer layer, and the dermis, or inner
layer. Beneath these are the muscles and other tissues that the skin
covers (Fig. 4.49).

\\Fig. 4.49. (A)\ The skin and cycloid scales of
a rohu fish\ ![\\(B) \A drawing of the skin
and integumentary system of a fish, showing scales, epidermis, dermis,
and muscle\ ](media/image132.jpeg)

**Fig. 4.49. (A)** The skin and cycloid scales (**B) **A drawing of the
skin and integumentary

rohu fish system of a fish, showing scales, epidermis,

Image courtesy
of [Rajesh dangi](https://commons.wikimedia.org/wiki/File:Fish_scales.jpg)
dermis and muscle

Image from Living Ocean

The **epidermis** is the top layer of the integumentary system. It is
made of several sheets of cells that cover the scales. As the cells age,
new cells growing underneath push older cells toward the outer surface.

In the epidermis of most fishes are cells that produce mucus, a slippery
material like runny gelatin, that helps the fish slide through the
water. The mucus wears off daily, carrying away microscopic organisms
and other irritants that might harm the fish. The odor typical of most
fish comes from chemicals in the mucus.

In their epidermis, fishes have cells containing pigment grains that
give the fish its color. Some fish can change color by expanding or
contracting pigment cells. The changes are controlled by hormones that
are produced by the endocrine system and regulated by the nervous
system.

The lower layer of the integumentary system contains blood vessels,
nerves for sensing touch and vibration, and connective tissue made of
strong fibers. A special layer of dermal cells secretes chemicals to
produce scales, which grow larger as the fish grows. Most fish have
covering scales that protect them from damage when they bump into things
or are attacked. As the scales grow, they form concentric rings in some
fishes. These growth rings can be used to determine a fish's age. A few
fish, such as catfish, have no scales.

Skeletal and Muscular Systems
-----------------------------

The skeletal system supports the soft tissues and organs of the fish
(Fig. 4.50). The skeleton also protects organs and gives the body of the
fish its basic shape. The many bones of the skull form a rigid box that
protects the brain. Holes, hinges, and pockets in the skull allow room
for the nostrils, mouth, and eyes.

\\Fig. 4.50. (A)\ The skeleton of a cod
fish\ ![\\(B)\ A drawing of a fish skeletal
system\ ](media/image134.jpeg)

**Fig. 4.50. (A)** The skeleton of a cod fish (B) A drawing of a fish
skeletal system

Image courtesy
of [Olaf](https://en.wikipedia.org/wiki/File:Szkielet_dorsza.jpg) Image
from Living Ocean

The **vertebral column**, or backbone, is not a solid rod. The backbone
is actually a string of small bones called vertebrae. See Fig. 4.51.
Each vertebra has a small hole in it. Together, the small holes in the
vertebrae form a canal through which the spinal cord passes. The
vertebrae bones protect the spinal cord. Spaces between the vertebrae
allow the backbone to bend and nerves to reach the tissues and organs of
the body. Rib bones protect the body cavity. Additional bones support
the spines and rays.

\\Fig. 4.51. (A)\ A photo of the vertebrae of a
small fish\ ![\\(B)\ A drawing of a fish
skeleton vertebrae viewed from the front, showing rib and tail
sections\ ](media/image136.jpeg)

**Fig. 4.51. (A)** A photo of the vertebrae of **(B)** A drawing of a
fish skeleton vertebrae

a small fish viewed from the front, showing rib and

Image Courtesy
of [Assianir](http://https/commons.wikimedia.org/wiki/File:Vertebre_pesce_20130806_04.jpg)
tail sections

Image from Living Ocean

**Muscles** are tissues that contract to shorten and relax to lengthen.
Fish move by contracting and relaxing their muscles. Like humans, fish
have three types of muscles: skeletal muscles, smooth muscles, and heart
muscles.

The muscles and bones of a fish work together. **Skeletal muscles** use
bones as levers to move the body. **Tendons** are strong connective
tissues that attach muscle to bone. When muscle cells are stimulated,
they contract and shorten, which pulls on tendons to move bones.

Skeletal muscles are voluntary, meaning that they move only when the
thinking part of the brain signals them to move. To swim, fish must
contract and relax their skeletal muscles, just as humans do when they
learn to walk. Most of a fish's body is made of layers of skeletal
muscle. These layers are arranged in W-shaped bands from belly to back
(Fig. 4.52). This network of muscles is vertical and interlocking, which
allows the fish to move the body back and forth in a smooth, undulating
motion. Such motion would not be possible if the muscles ran
horizontally along the length of the body, from head to tail.

\(A) Side view of salmon skeletal\ ![\(B) Drawing of
skeletal muscle pattern in a fish\ ](media/image138.jpeg)

\(A) Side view of salmon skeletal (B) Drawing of skeletal muscle pattern
in a fish

Image courtesy of [Flying
Penguin](https://en.wikipedia.org/wiki/File:Henneguya_salminicola_in_flesh_of_coho_salmon,_BC,_Canada.JPG)
Image from Living Ocean, CRDG

A fish swims by alternately contracting muscles on either side of its
body (See Fig. 4.53 B). Swimming begins when the muscles on one side of
the body contract, pulling the caudal fin toward that side. The sideways
movement of the caudal fin pushes the fish forward. Then the muscles on
the opposite side of the body contract, and the caudal fin moves toward
the other side of the body.

\\(A) \Sardines swim by contracting their tail
muscles\ ![\\(B)\ A drawing contrasting a
typical fish swimming movement with the movement of a typical human
swimming with dive fins.\ ](media/image140.jpeg)

**(A) **Sardines swim by contracting their tail **B)** A drawing
contrasting a typical fish

muscles swimming movement with the movement

Image courtesy of[ James
Kilfiger](https://commons.wikimedia.org/w/index.php?title=File%3ASardines.ogv)
of a typical human swimming with dive fins

Skeletal muscles are also attached to bones that move the fish's paired
fins. Fishes with wide pectoral fins, like wrasses, swim by flapping
their pectoral fins. Other fishes, like fast-swimming tunas, move mostly
with their caudal fin but use long, thin pectoral fins for steering.

Skeletal muscles also move dorsal fins. Faster-swimming fishes reduce
water drag by tucking in their dorsal fins while swimming.
Slower-swimming reef fishes have larger dorsal fins, which they
sometimes flare to protect themselves in encounters with other fish.

**Smooth muscles** move internal organs of the body and line tubes such
as the intestinal tract and blood vessels. Smooth muscles are
involuntary; they move without signals from the thinking part of the
brain. For example, smooth muscles automatically contract and relax to
push food through the digestive tract from the mouth to the anus. Other
smooth muscles control the flow of blood and other body fluids and
movement in the urogenital tract.

**Heart muscles** are also involuntary. However, the structure of heart
muscle cells is different from involuntary smooth muscles, so these two
muscle types are given separate names. Heart muscles pump blood through
the blood vessels by rhythmically contracting and relaxing.

**Respiratory System**\
The respiratory system takes oxygen (O2) into the body and passes carbon
dioxide (CO2) out of the body. Oxygen is essential to fish's digestion
because it combines with food molecules to release energy for the fish's
needs.

The respiratory organs in fish are gills. Each gill has many gill
filaments, which contain a network of tiny blood vessels
called **capillaries** (Fig. 4.54). The **gill cover **(also called
the **operculum**) is the body surface that covers the gills. The **gill
rakers** filter food from the water as water passes out to the gills.

\\Fig. 4.54. (A)\ Exposed fish gills as viewed
from the ventral, or belly side, of the head\
![\\(B)\ A drawing of a gill filament with a gill
raker and the gill arch labeled\ ](media/image142.jpeg)

**Fig. 4.54. (A)** Exposed fish gills as viewed **(B)** A drawing of a
gill filament with a gill

from the ventral, or belly side, of the head raker and the gill arch
labeled

Image courtesy of [Uwe
Gille](https://commons.wikimedia.org/wiki/File:Gills_(esox).jpg) Image
from Living Ocean, CRDG

Water moves over the gills in a pumping action with two steps (Fig.
4.55). In the first step, the mouth opens, the gill covers close, and
the fish brings water into its mouth. In the second step, the mouth
closes, the gill covers open, and water passes out of the fish. This
action is called **buccal pumping** and is named for the cheek muscles
that pull water into the mouth and over the gills.

Some fish also use **ram ventilation** to move water over their gills.
When swimming fast, fish like sharks and tunas open both their mouths
and gill openings to let water pass continuously through their gills.
They do not need to open and close their mouth because water is pushed
over their gills by their swimming action.

As water passes over the gills, carbon dioxide in the blood passes into
the water through the capillaries of the gill filaments. The same gill
filaments allow dissolved oxygen from the water to pass into the blood,
which then carries it throughout the body.

\Fig. 4.55. Movement of water past the gills\

Fig. 4.55. Movement of water past the gills

Image from Living Ocean, CRDG, University of Hawaii at Manoa

**Buoyancy**
------------

**Buoyancy** refers to whether something will float or sink. Some fishes
have a gas bladder that helps control their buoyancy. The **gas
bladder** is a special, gas filled chamber in a fish's body cavity. It
lies just below the kidneys.

The gas bladder is often called the swim bladder because it regulates
buoyancy by making the fish's density equal to the density of the
surrounding water. The average density of seawater is 1.026 g/mL, but
the density of fish flesh and bones is about 1.076 g/mL. This means that
a typical fish is denser than seawater and would naturally sink. The
density of the gas bladder, on the other hand, is less dense than
seawater. The low density of the gas bladder helps the fish float (Fig
4.56).

![\\Fig 4.56. (A)\ The position of the gas
bladder (swim bladder) in a bleak (Alburnoides bipunctatus)\
](media/image144.jpeg)\\(B)\ Gas bladder from a
Ruddy fish (Scardinius erythrophthalmus)\

**Fig 4.56. (A)** The position of the gas bladder (swim **(B)** Gas
bladder from a Ruddy fish

bladder) in a bleak (*Alburnoides bipunctatus*) (*Scardinius
erythrophthalmus*)

Image courtsey
of [Wikimedia](https://commons.wikimedia.org/wiki/File:Air_bladder_in_a_bleak.jpg)
Image Courtesy
of [Wikipedia](https://en.wikipedia.org/wiki/File:Swim_bladder.jpg)

The gas bladder has a low density because it is filled mostly with
oxygen and nitrogen gases. The gas bladder acts like an inflatable
balloon inside the fish. The gas bladder reduces the density of the
fish's body until it is the same as the density of seawater. This helps
the fish float within the water column.

In many groups of fishes (like herring, pike, catfish, eels), an open
tube connects the gas bladder to the digestive tract. This allows the
fish to adjust gas content in the bladder by swallowing and expelling
air through their mouth. Other kinds of fishes (like perches, snappers,
groupers) have a gas gland that bubbles gasses into and out of the
bloodstream to inflate and deflate the gas bladder.

Pressure increases with increasing water depth because the water above
pushes down on the water (and animals) below. When a fish swims into
deeper water, its gas bladder gets smaller because of the increase in
water pressure. Thus, as a fish goes deeper, it must add gas to its gas
bladder to maintain neutral buoyancy. When a fish swims into shallow
water, its gas bladder expands because the pressure of water surrounding
the fish decreases. Thus, as it moves into shallower water, the fish
must absorb gas from the gas bladder to maintain neutral buoyancy.

Because gases move slowly in and out of the gas bladder, fish caught at
great depths are often bloated when they are brought to the surface
quickly. The gas in the gas bladder expands when the fish moves from the
high pressure of deep water to the lower pressure at the surface. A fish
pulled quickly to the surface cannot absorb the gases fast enough, and
the sudden expansion of the gas bladder can injure the fish (Fig. 4.57).

![\\Fig. 4.57.\ Inflated gas bladder of a deep
water rougheye rockfish after capture.\ ](media/image146.jpeg)

**Fig. 4.57.** Inflated gas bladder of a deep water rougheye rockfish
after capture.

Image courtesy of[ NOAA Fisheries: Alaska Fisheries Science
Center](https://www.afsc.noaa.gov/quarterly/jfm2013/divrptsABL2.htm)

To keep the fish alive, collectors must bring fish to the surface slowly
to let the fish's body absorb the gases from the gas bladder. There are
also methods for releasing a fish with recompression in order to help it
recover from gas expansion as a result of being brought quickly to the
surface (Fig. 4.58).

\Fig. 4.58. Recompression is lowering a fish to its natural depth in
a controlled manner, using devices like weights and baskets, and allows
gas in the gas bladder to be reabsorbed into the fish's body.\

Fig. 4.58. Recompression is lowering a fish to its natural depth in a
controlled manner, using devices like weights and baskets, and allows
gas in the gas bladder to be reabsorbed into the fish's body.

Image courtesy of[ NOAA Fisheries: West Coast
Region](http://www.westcoast.fisheries.noaa.gov/stories/2013/18_2013_06_19_preventing_barotrauma.html)

Some fishes, such as grunts and toadfish, can use their gas bladder to
produce sound. Muscles in the wall of the bladder contract rapidly,
producing a low-frequency (low-pitch) sound that is resonated and
amplified in the bladder. Other fishes, like the lungfish, also use the
gas bladder as an accessory respiratory organ or "lung" when they crawl
on land.

Fishes that have no gas bladder are always denser than the surrounding
water, so they sink if they stop swimming. Sharks, for example, must
keep swimming to stay afloat. They use their tails and pectoral fins
like airplane wings, adjusting the amount of lift to control the depth
of their swimming. Many bottom-dwelling fishes also lack gas bladders
because they have no real need from them.

Circulatory System
------------------

The circulatory system is a transportation system for body fluids. The
circulatory system brings nutrients to cells and carries waste away from
cells. **Blood** is a fluid that consists of plasma (the liquid part)
and blood cells. Plasma contains water, carbon dioxide (CO2), hormones,
nutrients, wastes, and other molecules. Blood cells are of two main
types: red and white.

Red blood cells carry oxygen (O2) from the gills to other cells in the
body. In red cells, special molecules that combine chemically with
oxygen can pick up and release oxygen, depending on the surrounding
environment. These molecules, called hemoglobin, contain iron atoms.
When hemoglobin combines with oxygen, it turns bright red. When
hemoglobin releases its oxygen, it turns a very dark red.

White blood cells fight disease. They often concentrate around infected
wounds, killing bacteria and transporting wastes away from the wound.
Dead cells in a wound form pus, which white blood cells help to
eliminate.

A network of tubes called **arteries**, **capillaries**,
and **veins** connects the heart with all parts of the body (Fig. 4.59).
The arteries carry blood from the heart to the capillaries. The
capillaries, microscopic in size and very numerous, have thin walls
through which nutrient molecules can move. The molecules move through
the walls of the capillaries and into the fluids around the tissues. The
veins carry blood from the capillaries back to the heart.

![\\Fig. 4.59.\ Schematic of a fish's circulatory
system, showing only the major systems. All parts of the body are served
by arteries, capillaries, and veins.\ ](media/image148.jpeg)

**Fig. 4.59.** Schematic of a fish's circulatory system, showing only
the major systems. All parts of the body are served by arteries,
capillaries, and veins.

Image from Living Ocean, CRDG, University of Hawaii at Manoa

The **heart** pumps blood to all parts of the body. The fish heart has
one ventricle and one atrium. In comparison, the human heart has two
separate ventricles and two separate atria. In the fish heart, there are
also two other chambers: the sinus venosus (before the ventricle) and
the bulbus arteriosus (after the atrium). (See Fig. 4.60.)

\\Fig. 4.60.\ Contraction of heart muscles moves
blood through the system.\

**Fig. 4.60.** Contraction of heart muscles moves blood through the
system.

Image from Living Ocean, CRDG, University of Hawaii at Manoa

When the heart muscle contracts, it forces blood into the arteries.
Valves between the chambers allow the blood to flow in only one
direction. Blood that is low in oxygen and high in carbon dioxide is
pumped to the gills, where it releases carbon dioxide and picks up more
oxygen through capillaries in the gill filaments. The blood, now rich in
oxygen, flows through branching arteries to the brain, digestive system,
and other tissues and organs.

As it passes through the digestive system, the blood absorbs nutrients
and distributes them through the body. As it passes through each tissue
and organ, some of the blood plasma passes through capillaries and flows
around the cells. Oxygen and nutrient molecules move from the plasma
into the cells. Carbon dioxide and waste products move from the cells
into the plasma. The plasma then passes back into the capillaries and
carries waste away.

Another network of tubes, called **lymph ducts**, picks up the liquid
that passes out of the capillaries and collects in parts of the fish's
body. The lymph ducts return this liquid (called **lymph**) to the
veins.

### Digestive and Excretory System

A fish's **digestive and excretory system** includes the structures and
organs that bring food into the body, break food down into usable
substances organism, and remove unused food. The digestive system begins
with the mouth and teeth, which trap food and help send it on to the
stomach and intestine for digestion. Undigested food and waste leaves
the body through the anus (Fig. 4.61).

The urinary portion of the **excretory system** also removes waste
produced by the body. Its chief organs are the **kidneys**, which are a
pair of long, dark-red organs under the vertebrae. The kidneys filter
small molecules from the blood. After filtering, usable materials such
as sugars, salts, and water are absorbed back into the blood. The
remaining waste products pass from the kidneys down the **urinary
tubes**, to the bladder, and out through an opening behind the anus,
called the **urogenital opening**. This is the same opening through
which materials from the reproductive system (eggs from the ovaries or
sperm from the testes) pass.

![\\Fig. 4.61\. Excretory and reproductive
systems of a fish\ ](media/image150.jpeg)

**Fig. 4.61**. Excretory and reproductive systems of a fish

Image from Living Ocean, CRDG, University of Hawaii at Manoa

The gills are also part of the excretory system. Blood carries waste
products and excess salts to the gill filaments. Carbon dioxide (CO2)
and ammonia are excreted by the gills. Fish living in seawater and
brackish water also excrete excess salt from their gills.

The liver also removes wastes from the blood. The liver cleans blood
after it has picked up digested products from the intestine. Wastes are
converted into bile and stored in the gall bladder, where they wait to
be poured back into the digestive tract to aid in digestion (Fig. 4.61).

**Osmosis** is the passive movement of water across cell membranes. If
two fluids have different salinities, water will cross the cell membrane
to balance the salinity on both sides. This means that the excretory
system is affected by where a fish lives.

Freshwater fishes have body tissues that are saltier than the
surrounding water. Thus, water constantly enters the body through the
gills and body cavities. Freshwater fishes must urinate frequently to
rid themselves of this excess water.

Saltwater fishes, by contrast, are surrounded by water that is saltier
than their bodily fluids. Water is always leaving their bodies. To
prevent dehydration, saltwater fishes drink constantly, and excrete
small amounts of very concentrated urine. Special salt glands in the
gills also help eliminate the salt from the water drank by the fish.