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Beautiful Reef

Tuesday, October 28, 2014

Common Saltwater Fish, Coral Diseases and Treatment

Common Saltwater Fish and Coral Diseases

A list of saltwater fish diseases and treatments are listed for you.  The most effective way to deal with diseases is to prevent it by reducing stress.  A varied diet, stable water temperature, good water parameters, daily observance, and responsible stocking are a few ways to ensure healthy fish, free of disease.  But even if you manage to deal with it, unfortunately it will still strike one or more of your saltwater fish. Fish will get sick. Pathogens that cause diseases are in and around your fish’s natural setting and in your aquarium. They may be bacterial, viral, fungal or parasitic. So when the fish's skin or tissue gets damaged, whether from shipping, netting or any other circumstances, bacterial and fungal pathogens seize the opportunity to infect the fish.  Poor water quality is another reason fish weaken the immune system. This could be another cause for fish diseases. 

The bad thing is that there’s not a lot of treatment available for us aquarists and there is no guarantee that our saltwater fish will be saved. We will cover diseases that are most common in your aquarium at home - how you’ll be able to recognize these fish diseases and treatments available.

Saltwater Fish Disease

Table of Common Saltwater Fish Diseases and Problems

Disease / Problem Symptoms and Treatment


Ammonia Poisoning

Red or inflamed gills. Fish are gasping for air at the surface.
Ammonia poisoning is easily preventable. Avoid adding expensive and less hardy tropical fish until the aquarium has cycled. For more information on cycling your aquarium please read about the nitrogen cycle. You can use a substance called zeolite or even better Purigen to help absorb ammonia but the best solution is to ensure that your aquarium has cycled and that your tank is not overcrowded. If your tank has not yet completed the nitrogen cycle, you will need to perform frequent water changes to keep the ammonia levels down.

Dropsy
Fish Disease - Dropsy

  • Names: Bloat, Dropsy
  • Disease Type: Bacterial (gram negative organism)

  • Cause / Organism:Multiple causes

Description:
Dropsy is an old medical term that was once used to describe swelling due to accumulation of fluids in the tissues or body cavities, such as the abdomen. Fish suffering from Dropsy often have a hugely swollen belly, hence the origination of the disease name.

The disease is actually an infection caused by bacteria that are commonly present in all aquariums. Consequently, virtually any species of fish can be stricken with Dropsy. However, healthy fish rarely fall prey to the disease. Fish are only susceptible when their immune system has been compromised by some stress factor. If all the fish in the tank are under stress, it’s quite common for the entire tank to become infected. It is also possible for only one or two fish to fall ill, especially when prompt action is taken to prevent spread of the disease.

As the infection progresses, skin lesions may appear, the belly fills with fluids and becomes swollen, internal organs are damaged, and ultimately the fish will die. Even with prompt treatment, the mortality rate is high. Only fish that are diagnosed in the early stages of the infection are likely to respond to treatment.
Symptoms:
Symptoms vary widely. Some fish present with the classic swollen belly, others display skin lesions, while still others show few symptoms at all. This variability is what makes diagnosis difficult. However, in most cases a number of symptoms are observed, both physical and behavioral. Those include:
  • Grossly swollen belly
  • Scales stand out (pinecone appearance)
  • Eyes bulge
  • Gills become pale
  • Anus becomes red and swollen
  • Feces pale and stringy
  • Ulcers form on the body along the lateral line
  • Spine may become curved
  • Fish clamps fins
  • Fish becomes lethargic
  • Fish stops eating
  • Fish hangs near the surface
These symptoms are the result of the progression of the infection. Internal organs are affected, most notably the liver and kidneys. Anemia occurs, causing the gills to lose their normal red color. As the abdomen fills with fluid organs are pushed aside, sometimes causing the spine to curve. Scales protrude from the body, giving the appearance of a pine cone. This symptom is a classic indication of a severe infection.

Cause:
The bacterial agent that causes Dropsy is one of several gram negative bacteria commonly present in aquarium habitats. The underlying cause of fish becoming infected in the first place is a compromised immune system that leaves the fish susceptible to infection. This can happen as the result of stress from a number of factors, such as the following:
  • Poor water quality
  • Ammonia or nitrite spikes
  • Large drop in water temperature
  • Stress from transportation
  • Improper nutrition
  • Aggressive tankmates
  • Other diseases
Generally a single or short-term exposure to stress will not compromise the ability of the fish to fight infection. In most cases of lowered immunity, the stress exposure has happened for an extended period of time, or several stress factors have occurred in rapid succession.

Treatment:
Dropsy is not easily cured. Some recommend that all affected fish be euthanized to prevent spread of the infection to healthy fish. However, if detected early it is possible to save affected fish. Treatment is geared towards correcting the underlying problem, and providing supportive care to the sick fish.
  • Move sick fish to a hospital tank
  • Add salt to hospital tank, 1 tsp per gallon
  • Feed fresh high quality foods
  • Treat with antibiotics
It is important to move the infected fish to another tank to separate them from the healthy fish. Meanwhile, perform a water change on the original tank and monitor the fish closely for appearance of symptoms. Salt should be added to the hospital tank, at the ratio of one teaspoon per gallon of water. Keep the tank scrupulously clean, and perform weekly partial water changes. Provide a variety of fresh, high quality food. Often this is enough to resolve the infection in cases that are not advanced. Keep the fish under observation for several weeks after symptoms disappear. 

Antibiotics should be used if fish do not immediately respond. A broad spectrum anti-biotic specifically formulated for gram negative bacteria is recommended. My preference is for Maracyn-Two . A ten day course is ideal for ensuring the infection is eradicated. However, you should always follow manufacturers directions for duration and dosage.


Prevention:
As in many diseases, prevention is the best cure. Almost all the factors that stress fish enough to cause them to be susceptible to infection can be prevented. Because poor water quality is the most common root cause of stress, tank maintenance is critical. Other factors to keep in mind include:
  • Perform regular water changes
  • Keep the tank clean
  • Clean the filter regularly
  • Avoid overcrowding the tank
  • Do not overfeed
  • Use flake foods within one month of opening
  • Vary the diet
If the tank is well maintained, and the fish fed a healthy diet, outbreaks of Dropsy are unlikely.


Hole in the Head - HITH, sometimes referred to as Head and Lateral Line Erosion - HLLE

A common contributing cause is the flagellate parasite Hexamita. This parasite primarily infects the intestinal tract, but then spreads to the gall bladder, abdominal cavity, spleen, and kidneys. As the disease progresses, the classical lesions of hole in the head disease appear. These lesions will open up and may discharge small white threads that contain parasitic larvae. Secondary bacterial or fungal infections may then develop in these openings and may lead to a more serious disease, and death.

Another popular theory is that a mineral or a vitamin imbalance may contribute to the development of this disease. Some aquarists have claimed a link between the use of activated carbon and an increase in the disease. Some people feel that the carbon may remove some of the beneficial minerals found in the water leading to an increased incidence in the disease. At the same time, the mineral imbalance may be caused by an increase in Hexamita organisms in the intestine, which may lead to malabsorption and a decrease in the absorption of the needed vitamins and minerals.

Conditions that create stress will also increase the incidence of this disease. Poor water quality, improper nutrition, or overcrowding are all stressors that can cause a problem. Because the disease is often associated with older fish, there may be a link with decreased function of the immune system in these older fish and an increase in the incidence of the disease.

Signs

The signs include pitting-type lesions on the head and lateral line. The condition may be mild at first, but if changes to the environment and treatment are not initiated, the holes will become larger and secondary bacterial and fungal infections will develop. These lesions can eventually create a severe infection and the fish becomes systemically ill with loss of appetite and death.

Treatment

Because there may be multiple causes of this disease, the treatment usually consists of taking a multi-faceted approach. The goal is to rid the fish of Hexamita, improve water quality, and improve vitamin/mineral supplementation and nutrition.

A common treatment for infection with Hexamita includes the addition of the antibiotic metronidazole to the treatment tank housing the infected fish. Water quality must be closely watched, and the water quality adjusted to the exact standards required for the fish. Improving nutrition by adding fresh or frozen meaty foods or vegetables in the form of seaweed strips or lightly steamed broccoli may help. Make sure to target the nutrition to the species you are treating. For example, some cichlids are primarily vegetarians, whereas oscars are carnivores. In cases where secondary bacterial infections are present, additional antibiotics such as Maracyn, Kanacyn, or Furan may be needed. When treating this or any disease, try to use a separate treatment tank and treat as soon as the first symptoms appear.

Prevention

Prevention primarily focuses on reducing any stress affecting the fish. Stress, whether in the form of parasites, poor nutrition, or poor water quality all cause a suppression of the fish's immune system, which makes them more susceptible to this or any other disease.
If you own cichlids, oscars, or discus this is a disease that may occur in your tank. Be able to recognize the disease and take prompt steps to initiate early treatment; provide optimum water conditions; and feed the best possible diet. If managed and maintained properly, your fish should improve and not develop the disease again in the future.

Marine Ich or Ick (Cryptocaryon)

Small white spots showing up mainly on the fins or in advanced cases it may look like your fish has salt all over it. The fish may seem to "flash" or rub against objects in the tank.
This is a fairly common fish disease and your local pet store or online store should have medication you can use. Ich usually arises due to stress. Many believe that you can increase the temperature of your water to 82 degrees Fahrenheit to speed up the cycle time of this parasite. Remove any carbon filtration before using medication (rid-ich) because the carbon will absorb the medication. Try to prevent this from happening by quarantining your fish in a separate tank before introducing them into your main tank. Saltwater ich is treatable if caught in the early stages. Move the fish to quarantine and medicate according to the directions on the bottle.

Nitrite/Nitrate Poisoning

Tropical fish are lethargic or resting just below the water surface and you are getting high readings on your nitrite/nitrate test kits.
Nitrite / Nitrate poisoning is not a disease but will kill your tropical fish. It results from having a large bio-load on the filtration system or from not performing enough water changes. Perform a partial water change immediately and monitor the nitrite and nitrate levels closely until the situation is resolved. You may have too many fish in the tank and will need to perform more frequent water changes.

Oxygen Starvation

Most or all of the fish are usually found at the water surface. They may be gulping at the surface with their mouths.
Check the temperature of the water. Higher water temperatures require higher levels of oxygen. You will need to increase the aeration in the tank with air stones or increase the flow rate with your filters. Try to decrease the temperature of the water by floating ice cubes in plastic baggies and turning off the tank light. If sun light is entering the tank from a nearby window, try closing the shades. Also, if you have an overcrowded aquarium you will definitely need to increase the aeration in your tank.

Velvet (Oodinium)

Marine velvet disease is one of the most common diseases that affects marine aquarium fish. It is known by a variety of names including; amyloodiniosis, marine oodinium disease, oodiniosis, and gold dust disease. The scientific name of the infecting organism is Amyloodinium ocellatum.Amyloodinium is a one-celled organism called a dinoflagellate because it has whip-like structures (flagella) which help it move. It is highly adapted to parasitism. There are many free-living dinoflagellates present in most aquatic environments, but this particular species is one of the few that will actually cause disease in fish. This disease is widespread and can cause serious illness and death in aquarium fish if not recognized and treated quickly and properly. This article will give a description of the disease and offer treatment and prevention strategies.

Risk factors

The number of organisms: Amyloodinium is present in a free-swimming and infective form in many aquatic environments. The organism is extremely hardy and can withstand a wide variety of salinity and temperature fluctuations. In the wild, the number of infective organisms that are found in the water in any particular area is very small. In aquarium environments, there is the potential for large numbers of organisms to be found in a very confined space.
The immune system of the fish: As with almost all parasitic infections, most fish can fight off minor infections providing their immune system is strong. Many fish that are caught from the wild, however, and then placed in an aquarium are very stressed and their immune systems are not able to fight off minor infections let alone the greatly increased numbers that may be present in an aquarium environment. Amyloodinium can infect any fish at any time, but it appears to be much more of a problem when new fish are brought into an aquarium. Adding a new fish to an aquarium is obviously very stressful for the new fish and can be stressful for the existing tank inhabitants as well. Fish that are properly quarantined and fed are not as stressed and are much less likely to become infected with the disease and to create an outbreak when transferred to the existing display tank.

Symptoms

The symptoms of marine velvet usually involve the skin and lungs. Mild infections will usually only infect the gills and the fish may show minimal symptoms. As the infestation becomes more severe, the gills will become inflamed, bleed, and the lung tissue will begin to die. The fish will show signs of irritation and distress, with rapid breathing and lethargy. As the inflammation increases, the fish will lose its ability to transport oxygen across the gill membranes resulting in a fish that shows symptoms of suffocation, and if treatment is not initiated, death will often result.
The skin is the site of attachment for the organism and in severe infections, small gold-colored spots will cover the skin, which can progress to create a "velvet" appearance which gives the disease its name. By the time the gold-colored velvet appears, however, the gills may be so infected that treatment is usually too late. Many fish die from this disease without ever showing any visible skin changes. It may be possible to visualize early forms of the infection on the skin by using indirect illumination. This works best on dark fish and can be done by shining a flashlight on the dorsal surface of a fish in a darkened room. Viewing infected fish against a dark background may also be helpful.

Life cycle

Illustration of Lifecycle 
  1. Trophont on skin of fish
  2. Trophont detaches and becomes a tomont
  3. Tomont divides
  4. Tomont releases dinospores that will attach to the fish
The life cycle of Amyloodinium is very similar to Ichthyophthirius multifiliis, which causes freshwater ich, and is composed of multiple stages. The free-swimming organism is called a dinospore. When it attaches to the fish's skin, it is called a trophont. The trophont feeds on the fish for several days and then detaches. Once detached, it is called a tomont. The tomont divides and produces between 64 and 256 motile infective dinospores that attach to the fish and become trophonts starting the life cycle all over again.


Diagnosis

Diagnosis is usually made based upon history and symptoms, but scrapings of the skin can be performed and the trophonts identified. Another technique is to place the infected fish in fresh water for several minutes and the organisms will drop off and float to the bottom. The surface water can be poured off and the sediment can be examined microscopically.

Treatment

Initiate treatment immediately because the disease has such a high mortality level if not treated quickly. Treatment for this disease is almost exclusively with copper. There has been some success reported with the use of the antimalarial drug chloroquine diphosphate but the drug is expensive, difficult to obtain, and therefore not a common treatment option. Copper comes in several forms including ionic and chelated forms. The chelated forms are supposed to be safer but the total amount used is higher, possibly offsetting the safety benefits.
Copper is very effective but can be ineffective or toxic if not used at very specific levels. Choose a high quality product, follow the directions closely, monitor the copper levels in the water, and adjust accordingly. When copper is used, the water should be tested twice a day for copper levels for the first few days, and then daily for the rest of the treatment period. Most sources recommend an ionic copper level of between 0.15 and 0.2 parts per million for a minimum of 14 days. Alkalinity and the presence of carbonate-containing substrates can impact the absorption and release of free copper in the water.
Copper is extremely toxic to invertebrates and should not be used in tanks where invertebrates are, or will ever be, housed. It is always best to use copper or any treatments in a quarantine tank and to only treat the infected fish. IfAmyloodinium does develop in a reef tank with invertebrates, it will be very difficult to rid the tank of theAmyloodinium as long as fish are present. Removing the fish to a separate tank and allowing the tank to run fish-free for a month is probably necessary. This will allow the organism to run through its life cycle and die out due to the lack of a host.
If Amyloodinium does strike your tank, you will want to make sure that the water quality and nutrition are at the highest possible levels. Do everything possible to reduce the stress level of your fish to allow their immune systems to fight off this disease. There is evidence that fish that contract Amyloodinium and recover develop some lasting immunity to the disease.
There are several very important things to remember when treating this disease:
  • Stressed fish are much more likely to develop the disease.
  • This disease is highly contagious.
  • The key to treating this disease is early detection and prompt treatment.
  • Most fish that show the severe skin form are probably too sick to respond to treatment.
  • Only the free-swimming dinoflagellate form of the organism (the dinospore) is susceptible to treatment.
  • Properly sized UV sterilizers will also kill the dinospores.
  • The encysted form is not susceptible to any treatment.
Prevention

Prevention is the best way to treat marine velvet disease.
Prevention is truly the best way to treat this disease. We know that this disease is extremely contagious, widespread, and targets stressed fish. This disease most commonly shows up in newly purchased fish but will then often spread to other fish in the tank. Remember that adding a new fish to a tank is stressful for the existing inhabitants as well, and if a new fish comes in with an existing case of marine velvet disease, many of the other fish in the tank could develop the disease. Quarantining new fish is one of the best things you can do to maintain the health of your tank and is critical in preventing outbreaks of marine velvet disease. A quarantine period of a few weeks in a properly functioning quarantine tank will allow the aquarist enough time to ensure the new fish is not harboring velvet or ich. In addition, quarantined fish can be hand fed, isolated from aggressive fish, and treated, if necessary, allowing them to get through this high stress time in the best possible condition. The first several weeks after entering the new home is the highest period of mortality and disease in marine fish. It is impossible to be too careful or spend too much time or effort during this critical time period.
Amyloodinium is a common and deadly disease, but if proper quarantine procedures are followed coupled with early recognition and treatment, you can hopefully avoid the damage caused by this disease.

Black Ich


Clown Fish with Ich

Saltwater Tangs showing small black spots on their sides.
Get a cleaner shrimp and keep your water parameters in line. Ammonia or nitrites high? Shame on you. Your tank isn't cycled and you have a whole mess of issues ahead. Wait until the tank has cycled before adding fish. High nitrates? Vacuum the sand and clean out the filters, empty protein skimmer more frequently. Also give those tangs more seaweed in their diet.




Other Names: Saltwater Ich, Cryptocaryon Irritans, Marine Whitespot Disease

Symptoms

Flicking and scratching against rocks and other surfaces, small white spots resembling sugar covering fins and body.  Small black dots (larvae) appear on the sides and fins of affected fish. They may have rapid breathing and stop feeding. Affected fish will scratch themselves on surfaces and swim erratically. They may also breathe abnormally and lose their appetite.

Description

This disease is highly infectious and can spread rapidly to other fish in the tank. Rapid treatment is highly recommended. If treated in a reasonable amount of time it is usually not fatal.

Treatment

If the infestation is minor, a 5-minute freshwater bath may prove effective. Discontinue the freshwater bath if the fish begins to become overly stressed. For more major infestations, use copper-based medications to kill the cryptocaryon parasites. In a reef tank environment, the infected fish must be moved to a hospital tank for treatment. Never add copper compounds to an aquarium containing invertebrates. Some new treatments have appeared on the market recently that claim to control parasites in the marine aquarium. Consult your local aquarium dealer for more information.

Prevention

Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows parasites to gain a foothold. Additionally, any new fish should be given a short freshwater bath and kept in a quarantine tank for two to three weeks before being introduced into the main aquarium. The use of an ultraviolet sterilizer has also been shown to help prevent outbreaks of this disease.

Cause: Planarian; Ichthyophaga sp., Paravortex sp.

Description

Flukes can infect fish by attaching to the gills or body wall and sucking blood or body fluids. Hooks generally attach the parasite to the host. Those flukes that are monogenetic are able to reproduce in an aquarium and become a problem. Larvae are free swimming and find a host to which they attach. Adults are able to crawl from host to host - they are unable to swim. If a fish knocks them off they will likely die because they must crawl to another host.

At least 2 genera, Paravortex or Ichthyophaga, can cause tang turbellarian, a fairly common disease. The larvae appear as tiny black dots on the surface of a brightly colored fish, feeding on the blood of their host. The worm releases from the host and falls to the tank bottom to become an adult, which reproduces to make free-swimming worms that find new hosts. Repeated cycles of reproduction can produce heavily infected fish.

Treatment: As the flukes are dislodged by treatment, care must be taken to avoid knocking them off in the main aquarium which may allow them to reach another host. Treatment should be done in a hospital tank:
  1. Freshwater baths, with formalin and malachite green. Parasites will fall off and should be destroyed.
  2. Praziquantel: 1-5 mg/L hospital tank.
  3. Trichlorfon (Dylox®) 1.0 mg/L daily for 3 days.


Drug Details For The Treatment of Tang Turbellarian, Black Ich, Black Spot Disease:
NameDosageActionPrecautionDangers
Formalin37% stock, .03 ml/L prolonged; 0.125 - 0.25 ml/L for brief dipsenzyme and cell membrane protein disruptiontoxic to fish and humansalgae, invertebrates, fish above 80°F
Malachite green2 mg/l brief dip, 0.1 mg/L continuousbinds and denatures intracellular proteinscarcinogenic, toxicpoisonous to fish
Freshwater Dipequalize pH, temperature, 5 minute limitcauses osmotic imbalance that leads to plasmolysis - rupture of the celltoxic procedure, difficult to move and handle sick fish without harming them furthernot used on fish with open wounds
Praziquantel1 mg/L/3-5 days aqueous; 2.5 mg/1 g food orallyeither causes calcium imbalance and parasite paralysis or prevents parasite purine sysnthesismust be used in a hosptital tankkills some invertebrates, such as feather duster worms


Marine Velvet Disease


Other Names: Saltwater Ich, Coral Fish Disease, Oodinium, Amyloodinium Ocellatum

Symptoms: Flicking and scratching against rocks and other surfaces, rapid breathing, tiny white spots covering the body that give it a white velvet appearance.
Description: This is without a doubt the most infectious and deadly marine fish disease. The tiny parasites multiply quickly and eventually move into the gill plates of the fish causing slow suffocation. It can easily spread to other fish in the tank. If not treated immediately, it can cause death in only a few days. Rapid treatment is mandatory for the survival of the fish.
Treatment: Use copper-based medications to kill the amyloodinium parasites. In a reef tank environment, the infected fish must be moved to a hospital tank for treatment. Never add copper compounds to an aquarium containing invertebrates. Some new treatments have appeared on the market recently that claim to control parasites in the marine aquarium. Consult your local aquarium dealer for more information.
Prevention: Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows parasites to gain a foothold. Additionally, any new fish should be given a short freshwater bath and kept in a quarantine tank for two to three weeks before being introduced into the main aquarium. The use of an ultraviolet sterilizer has also been shown to help prevent outbreaks of this disease.

Black Spot Disease

Symptoms

Flicking and scratching against rocks and other surfaces, small black spots on the body.
Description: This disease is caused by small parasitic worms. The black spots are usually not as numerous as those in white spot disease. Also, black spot disease is not nearly as deadly.

Treatment

If the infestation is minor, a 5-minute freshwater bath may prove effective. Discontinue the freshwater bath if the fish begins to become overly stressed. For worse cases, use a copper or trichlorofon based solution. In a reef tank environment, the infected fish must be moved to a hospital tank for treatment. Never add copper compounds to an aquarium containing invertebrates. Some new treatments have appeared on the market recently that claim to control parasites in the marine aquarium. Consult your local aquarium dealer for more information.
Prevention: Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows parasites to gain a foothold. Additionally, any new fish should be given a short freshwater bath and kept in a quarantine tank for two to three weeks before being introduced into the main aquarium. The use of an ultraviolet sterilizer has also been shown to help prevent outbreaks of this disease.



Fish Disease Gill Flukes
Fin flukes fish Disease
Gill and Fin Flukes

Symptoms: Flicking and scratching against rocks and other surfaces, rapid breathing, cloudy eyes, white patches on body, worm-like parasites sometimes visible but not always.

Description: This is another disease that is highly infectious and can be fatal if not treated quickly. It is caused by small worm-like parasites. They multiply quickly and can clog the gill of the fish causing slow suffocation.

Treatment: A freshwater bath will provide immediate relief for the fish by killing most of the parasites. A long saltwater bath with methylene blue is also helpful. Some new treatments have recently been introduced. Contact your local aquarium dealer for more information about these.

Prevention: Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows parasites to gain a foothold. Additionally, any new fish should be given a short freshwater bath and kept in a quarantine tank for two to three weeks before being introduced into the main aquarium. The use of an ultraviolet sterilizer (UV Sterilizer) has also been shown to help prevent outbreaks of this disease.

Virus and Bacterial Infections

Bacterial Finrot
Freshwater Fish Fin Rot Fish Disease

Symptoms: Erosion of fins and fin rays, reddened areas, lethargy, poor appetite.
Description: This disease is usually associated with stress, sometimes brought on by poor water quality. Healthy animals can usually resist infections. Finrot usually begins as a mild external infection causing a reddening of the base of the fins. In severe cases, the animal's body and mouth may be eaten away.

Treatment: Identify the source of stress and correct the problem. If this does not correct the problem, the animal should be treated with antibiotics or Melafix in a hospital tank. Adding antibiotics to the main aquarium can kill invertebrates and damage the biological filter. Melafix for maar20ine environments are usually always reef safe but look for it stating that on the bottle.  Follow the instructions.
Marine Fin Rot Bacterial

Prevention: Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows bacteria to gain a foothold. The use of an ultraviolet sterilizer may help prevent outbreaks of this disease.

Bacterial Infection

Other Names: Pseudomonas,Vibrio

Symptoms: Reddened, frayed fins with open sores, rapid respiration, cloudy eyes, poor appetite, lethargy, weight loss, abdominal swelling.

Description: This disease is usually associated with stress, sometimes brought on by poor water.
 quality. Healthy animals can usually resist infections.

Treatment: Identify the source of stress and correct the problem. If this does not correct the problem, the animal should be treated with antibiotics in a hospital tank. I prefer to use Melafix by adding antibiotics to the main aquarium it is invert and reef safe.

Prevention: Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows bacteria to gain a foothold. The use of an ultraviolet sterilizer may help prevent outbreaks of this disease.

Lymphocystis

Other Names: Cauliflower Disease

Symptoms: Small warty clumps on the fins that resemble small cauliflowers.

Description: This disease is caused by a virus and often looks worse than it is. It is rarely fatal and will usually clear up on its own if optimum water quality is maintained.

Treatment: There is no effective treatment for this disease. A short freshwater dip may help. Maintain optimum water quality and symptoms should improve with time. If a secondary bacterial infection should occur, move the animal to a hospital tank and treat with antibiotics.

Prevention: Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows the virus to gain a foothold. Additionally, any new fish should be given a short freshwater bath and kept in a quarantine tank for two to three weeks before being introduced into the main aquarium.

Other Aquarium Diseases

Marine Fungus

Other Names: Ichthyophonus, CNS Disease

Symptoms: Darkening in color, sandpaper appearance of skin, poor appetite, listlessness.

Description: Fungal spores are present in all aquariums but, if you are not careful, they can become a problem in the saltwater tank.


When cultivating a saltwater aquarium there are a variety of elements you must monitor and control. In addition to keeping your water quality high and your salinity levels stable, you also have to be on the lookout for harmful bacteria and fungus entering the tank. While most aquariums naturally contain some fungus and bacteria, if these organisms are allowed to grow out of control they could contribute to a number of problems in your tank. Filamentous fungus, for example, can be a serious problem in the marine tank. Other forms of fungus may include fungal infections which affect the bodies of fish and egg fungus which can quickly kill fish eggs. To prevent fungus from causing problems in your saltwater aquarium, take the time to learn the basics about how these infections start and what you can do to prevent them.
What is Marine Fungus?


Live marine fungus typically consists of a mass of threadlike filaments called hyphae that grow together in clumps to form mats. Certain types of fungus grow downward into the organic matter on which they are feeding, acting much like the roots of live plants. Other types of fungus grow outward, spreading in the form of fluffy growths. As the fungus grows and spreads, sporangia will form on the tips of the filaments – these sporangia contain spores which will be released into the tank water when the sporangia mature and rupture. Fungus feeds on all kinds of organic matter – fish waste is one the most common foods that they ingest, along with uneaten fish food. Certain types of fungus also exhibit parasitic qualities, feeding on the bodies of fish that have already been damaged by stress, injury or disease.


Marine Fungal Infections


There are several different types of marine fungus, some of which are normally harmless to aquarium fish. Saprolegnia fungi, for example, are common in all types of aquariums and they typically feed on organic waste like dead fish and uneaten fish food. In cases of poor water quality, however, this fungus may start to grow on aquarium fish, especially if its gills or skin have already been damaged. Overcrowding and stress in the saltwater aquarium may also increase the likelihood that normally harmless fungus will begin to attack your fish.


The most common type of fungal infection in saltwater and freshwater aquarium sis body fungus – this type of infection is very distinctive and generally easy to diagnose. These fungal infections typically manifest in the form of fuzzy patches growing on the body or fins of infected fish. As the infection spreads, the growths may become enlarged and could begin to take on a green or brownish tint as a result of debris particles becoming trapped on the filaments. Once this type of fungal infection sets in, it can quickly spread throughout the body of infected fish. Though the infection usually does not penetrate any deeper than the superficial muscle and gill layers of the body, it can cause severe damage. Some fungus may also excrete harmful chemicals that can weaken the immune systems of infected fish, leaving them more susceptible to secondary infections.


Treatment Options


The key to dealing with marine fungus in the saltwater aquarium is to take action as soon as you recognize the problem. While you may be tempted to tackle the infection itself first, your first step should be to remedy the underlying cause of the infection. In many cases, fungal infections are precipitated by a drop in water quality or an increase in stress. Test the water in your aquarium to make sure the water parameters are in line and make adjustments if necessary. If you are able to determine that water quality is not the issue, look for other sources of stress in the tank. If one or more of your fish are particularly aggressive, it could cause the rest of your fish to become stressed. Physical injury as a result of aggressive tank mates or unsafe aquarium decorations may also be a problem.


After you have determined and remedied the underlying cause of the fungal infection you can move on to treating the infection itself. You will not be able to completely remove the fungal spores from your aquarium because they are resistant to treatment. Fortunately, it is unnecessary to remove all of the spores from the tank because they will not harm your fish unless they are already weakened by stress or injury. To deal with fungal infections you should quarantine the affected fish in a hospital tank and treat the water with an anti-fungal medication like Pimafix. There are many anti-fungal medications available including malachite green and formalin – salt may also be an effective treatment for some fungal infections. When treating your fish, make sure to remove any activated carbon from your aquarium filter and follow the dosing instructions carefully. If the infection is particularly stubborn, you may need to use potassium permanganate – this product can be toxic in water with a high pH, so use this product very carefully.


Treatment: Treatment for this disease is difficult. Improve the environment and remove any possible causes of stress. Try a proprietary anti-fungal medication in a hospital tank. Food soaked in phenoxetol can also be effective if the fish is eating.  The best way to deal with fungus in the saltwater aquarium is to maintain high water qualityso it does not become a problem. Remember, fungal spores are present in all aquariums and they are generally not harmful to fish under normal conditions. If the water quality in your tank drops, however, or your fish become stressed you may have problems with fungal infections.

Prevention:  Insure good water quality and temperature parameters to prevent animals from getting stressed. Stress breaks down the protective mucous coating on a fish and allows the fungus to gain a foothold. Additionally, any new fish should be given a short freshwater bath and kept in a quarantine tank for two to three weeks before being introduced into the main aquarium.

HLLE Fish Disease


Head and Lateral Line Erosion

Other Names: HLLE

Symptoms: Erosion of the lateral line and the formation of pits in the skin.

Description: This disease is usually caused by poor environmental conditions and poor water quality. If conditions are not improved, the condition of the fish will slowly deteriorate and the animal may die.

Treatment: Improve environmental conditions, maintain optimum water quality and proper diet. The use of vitamin supplements may help.

Prevention: Insure good water quality and temperature parameters. Maintain healthy diet.

Poisoning

Other Names: None
Symptoms: Erratic behavior, darting around the tank, rapid breathing, gasping at surface.

Description: This condition can be caused by the introduction or overdosing of medications, heavy metals, chlorine or chloramine, household chemicals, or other toxic substances. Immediate action is required to prevent poisoning or permanent damage.

Treatment: Remove the pollutants from the tank through water changes and the use of filter media such as activated carbon. If the condition is critical, move the animals to a tank with clean water.

Prevention: Maintain proper water quality and try to prevent the addition of external toxins. A cover for the aquarium may help. Follow instructions carefully when using medications.

Malnutrition

Other Names: Poor Diet

Symptoms: Tendency to bloat after feeding, sunken stomach, thinness, listlessness, loss of color.

Description: The symptoms of malnutrition can be similar to other diseases.

Treatment: Provide a good, varied diet. Use the right kinds of food for each animal. Use of vitamin supplements may also be helpful in recovery.

Prevention: Insure proper feeding and proper diet. Avoid overfeeding.

Aquarium Pests

brown_algae_Kai_Schreiber.jpg - Kai Schreiber
Brown Algae

Other names:  Diatoms

Symptoms: Fuzzy brown patches on the glass of the aquarium that eventually spread to the rocks, sand, and decorations.

Description: Brown algae is a common occurrence in newly set up aquariums. It is not really an algae. It is actually a colony of microscopic creatures called diatoms. Brown algae is usually caused by excess silicates and nitrates in the water. It can also be caused by inadequate lighting. Silicates can be introduced into the water through of tap water. Avoid using tap water if possible. Silicates can also leech from some substrates. Avoid using colored gravel from the pet store. Using aragonite sand or crushed coral as a substrate will help reduce silicate levels.

Treatment: Wipe the glass regularly with a good quality aquarium scraper. Magnetic scrapers are available that will let you clean the glass without having to get your hands wet. Brown algae is commonly caused by excess silicates and nitrates in the water. Check nitrate levels and perform regular water changes with pure quality water.

Prevention: Brown algae usually goes away after a new aquarium becomes established. If you continue to have problems, make sure to perform regular water changes once or twice per month. Regular water changes are the best way to control algae. If you don't have one, install a good quality protein skimmer to remove organic waste. You can also install a phosphate reactor to remove phosphates from the water. Make sure to use pure water. Consider investing in an RO/DI water filtration system. Also, make sure you are using lights that are made for aquarium use. Make sure the bulbs are not too old. Fluorescent bulbs should be replaced every 12 - 18 months. After that, the wavelength of the light changes and can encourage algae growth. Make sure you are not leaving the lights on for more than ten hours each day.

Hair Algae

Symptoms: Long strands of green algae that resemble hair growing on the rocks, decorations, or filters.

Description: Hair algae gets its name from its appearance. It resembles green hair growing in the aquarium. It is caused by an excess of nitrates and phosphates in the water. Once established, hair algae can spread quickly and can completely overcome the tank if not properly treated.

Treatment: Test your water for phosphates and nitrates. If phosphates are high, you can get find a variety of phosphate filter media at your local aquarium store. Follow the directions closely. Do not leave the filter in the water for longer than the suggested use. If left in too long, the filter can actually leak phosphates back into the water. If nitrates are high, perform regular water changes with good quality water. Do not use tap water.

Prevention: Hair can be controlled by maintaining good water quality. Make sure to perform regular water changes once or twice per month. If you don't have one, install a good quality protein skimmer to remove organic waste. You can also install a phosphate reactor to remove phosphates from the water. Make sure to use pure water. Consider investing in an RO/DI water filtration system. Also, make sure you are using lights that are made for aquarium use and that the bulbs are not too old. Fluorescent bulbs should be replaced every 12 - 18 months. After that, the wavelength of the light changes and can encourage algae growth. Make sure you are not leaving the lights on for more than ten hours each day. You may also want to add some herbivores to your tank. Blue-legged hermit crabs, sally lightfoot crabs, tangs, and turbo snails make good choices for controlling algae. If your aquarium is set up for invertebrates, you will want to keep several hermitcrabs and turbo snails as part of your "clean-up crew". You may also want to consider using live sand in your aquarium. Live sand contains microorganisms that can help to remove nitrates from the water.



Bubble Algae

Symptoms: Dark green, black, or red bubbles that look like they are made of plastic are attached to the rocks and sometimes on the glass and filters.

Description: This is actually a form of algae. The bubbles, also known as vesicles, are small bladders that contain water. These vesicles also contain spores. When the vesicle grows large enough, it will pop and release thousands of spores which will travel around the aquarium to form new vesicles. Bubble algae of a number of different species with slightly different shapes and colors, but they all pretty much have the same characteristics. Bubble algae is notoriously hard to eliminate once it gets established.

Treatment: The first step for treatment is to manually remove as much of the algae as possible. Carefully remove the bubbles using a sharp instrument such as a sharpened screwdriver or razor blade. Be careful not to pop the bubbles as this can actually help the algae spread. Part two of the treatment involves the use of herbivores. Emerald crabs can be particularly useful eliminating bubble algae and preventing its return. Hermitcrabs and sally lightfoot crabs can also be useful. It has been reported that some red-leg hermit crab species will also eat bubble algae.

Prevention: Prevention of bubble algae is pretty much the same as for all algae. You must reduce the algae's food supply by removing nutrients from the water. A really good protein skimmer is a good investment for any serious aquarist. A phosphate reactor can also help to remove excess nutrients from the water. Regular water changes are also necessary if you want to prevent algae from growing. Make sure to use pure water. Consider investing in an RO/DI water filtration system.

Cyanobacteria 

Other name:  Cyanobacteria
Slime Algae

Symptoms: Dark red or brown algae that covers the rocks and sand, resembling velvet. It has a slimy texture and will sometimes be seen with small air bubbles on it. Slime algae tends to peel off in large slimy sheets.

Description: This is not actually an algae at all. It is a form of bacteria known as cyanobacteria. It is one of the oldest forms of life on earth and may represent an evolutionary link between bacteria and algae. It may start out in small patches and slowly spread throughout the aquarium.




Treatment: Commercial antibiotic treatments for slime algae are available at your local aquarium store. They vary slightly from one brand to the next, so make sure you read the instructions thoroughly and follow the directions exactly. Improper use of antibiotics can affect the beneficial bacteria that filter the water. Monitor ammonia and nitrite levels after use to make sure your biological filtration has not been damaged. Most of these treatments are safe for use in a reef aquarium as long as you follow the directions exactly. When used properly, these treatments are effective for controlling slime algae outbreaks.

Prevention: Slime algae is usually caused by high levels of nutrients and organic waste in the water. Make sure to perform regular water changes once or twice per month. Regular water changes are the best way to control algae. If you don't have one, install a good quality protein skimmer to remove organic waste. You can also install a phosphatereactor to remove phosphates from the water.


Asterina Starfish

Symptoms: Tiny, white, gray, or green spotted starfish all over the rocks and aquarium glass. They are no larger than your pinky thumbnail and will be seen to have between two and five legs of varying lengths.

Description: These starfish are known as asterina. They are an invasive species that is commonly added to the aquarium as a hitchhiker on live rock or coral when it is added to the aquarium. The starfish multiply by breaking off their legs. Each leg that breaks off will grow into a new starfish in a matter of days. Once introduced, asterina can quickly overcome a reef tank and can decimate your coral. There is some debate within the aquarium community as to whether asterina will eat coral. There is a large debate on these little guys.  I have some and they are not a problem.  Others say they can eat your zoas and corals.  I have never personally seen that.   It started out with just a few starfish and then within months there were literally thousands of them. I recently had an outbreak in my aquarium and within a few months all of my zoanthids had completely disappeared. I also lost a torch coral. They even removed nearly all of the coralline algae from my live rock.

Treatment: The only effective treatment for an asterina invasion is control by means of the harlequin shrimp. The diet of the harlequin shrimp consists solely of starfish. I added two harlequin shrimp to my reef aquarium and within six months the asterina were gone.  But remember when the starfish are gone they are starving.  you might want to lend this animal around or trade out at your LFS.   If you have any other starfish in your aquarium, you will have to remove them before adding the harlequin shrimp. They will eat every starfish they can find.
Prevention: Since asterina are introduced to the aquarium as hitchhikers, the only known prevention method is to thoroughly examine every piece of coral or live rock before introducing it to your aquarium. Remove any asterina stars you may see in your tank before they multiply to biblical proportions.

Aiptasia Anemones

Symptoms: Small, clear to pink anemones growing on the rocks and/or glass in the aquarium. The have a circular disk and long pointy tentacles.

Description: Aiptasia are one of the banes of the marine reef aquarium hobbyist. They are an invasive species that is commonly added to the aquarium as a hitchhiker on live rock or coral when it is added to the aquarium. They multiply quickly and can take over a reef aquarium if not treated. They can sting fish and damage corals. Larger anemones have even been known to catch and eat smaller fish.

Treatment: When treatment of aiptasia you have two choices: chemical or biological. Chemical treatments are commercially available that can work quite well if you are persistent. They are marketed under names like Joe's Juice or Aiptasia X. I have had good results with Aiptasia X. The only thing is that you have to insert the tip of the syringe directly into the mouth of the anemone in order to kill it or it will just spread.  This can be challenging and may take a few times to actually succeed in accomplishing that.  These products are applies directly to the anemone using a small syringe. Within minutes the anemone will shrivel and implode. The only problem with these products is that the anemone will grow back, so you have to be diligent and keep using it until they are gone. The products are safe for use in a reef aquarium. A biological treatment is also available in the form of a fish. The aiptasia eating filefish, or matted filefish (Acreichthys tomentosus) will eat the anemones and can completely clean out a serious infestation in a matter of months. I personally keep the copperbanded butterfly fish.  It might take a little time to get them to eat it but when they do your tank will be aiptasia free.  I would suggest going with the Aiptasia X for small infestations and the filefish or copperbanded butterfly fish for large infestations.

Prevention: Since aiptasia are introduced to the aquarium as hitchhikers, the only known prevention method is to thoroughly examine every piece of coral or live rock before introducing it to your aquarium. Treat any aiptasia with Aiptasia X or similar remedies as soon as you see them to prevent them from spreading and becoming a problem.

Coral Diseases and Syndromes

Reports of coral disease are increasing in the wild and have often been linked to changes in the climate, specifically rise in sea temperatures. In aquarium systems diseases are also a major cause of concern and often result in mortality. Small coral frags can often die overnight and there is not usually much chance of a remedy. However in cases with reef tanks containing larger colonies, diseases can take longer to take effect and many blog sites report attempts at curing these diseases, from fragmentation, quarantine, administration of antibiotics or commercial products aimed at specific diseases. Here we report the main diseases commonly associated with aquarium diseases and suggest potential causes and likely ways to manage or mitigate them.

White Syndrome

Background:

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White Syndrome (WS) is a collective term for coral disease lesions showing a sharp demarcation between apparently healthy coral tissue and the bare coral skeleton, where the tissues have been removed rather than becoming pale or 'bleached'. You often need to look very close (sometimes with the aid of a magnifying glass) to distinguish between the two and tell whether there are any coral tissues still covering the skeleton. This disease, if left alone, will often result in total colony mortality, with the lesion advancing more quickly as it progresses to the last remaining fragments of live tissues. WS has been reported worldwide in the wild and in aquaria. WS displays variable rates of lesion progression and patterns of tissue loss, which has led to numerous alternative descriptions and definitions. The two most commonly referred to with regard to aquarium corals are: Rapid Tissue Necrosis and Shut Down Reaction.

Causes:

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Most scientific papers and blog sites will accredit this disease to bacteria of the genus Vibrio. However, it is not clear whether these are primary pathogens causing the disease or secondary colonisers invading the tissue once other microbes have caused damage. Relatively high abundances of Vibrio species live in healthy coral tissue and environmental samples such as aquarium sand. Recent research (Sweet & Bythell 2012) has shown the presence of protozoan's known as ciliates in corals showing signs of WS, and these ciliates can be seen to ingest the coral's endosymbiotic algae (zooxanthellae), suggesting an active role in WS pathogenesis. So the actual microbial agent responsible for WS has not been satisfactorily identified, and there may be several agents working in parallel.

Management or Mitigation:

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Fragmentation of the coral at least 1 cm above the disease lesion is currently the best method to save parts of colonies affected by this disease. Other treatments such as freshwater dips (15ppt), iodine dips (use 40 drops per 4.5 litres and immerse coral for 10-15 min), sealing of the disease lesion with marine putty and antibiotics and/or natural extracts such as tea tree oil have been shown by a few to succeed. However it likely depends on the size of your colony and how quickly you catch it - corals that are already immunosuppressed will often not reposnd well to further treatments. Isolation of any samples showing this disease will stop the spread to other corals. However, the underlying cause of the disease is usually a physiological stress, so always check and adjust aquarium water parameters when needed if WS develops.

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Brown Jelly Syndrome

Background:

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Brown Jelly Syndrome (BJS) is, as the name suggests, characterised by a brown mass resembling jelly. It appears to be floating on the surface of the coral and moves. This disease is also often associated with a rotten smell if handled. BJS appears to be restricted to aquaria and no reported wild diseases are similar in appearance. Tissue loss is fast and the disease is very contagious, so can spread to other corals regardless of species. 

Causes:

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Although the underlying cause may not be known, the pathology of this disease is characterised by very large numbers of the ciliate commonly referred to as Helicostoma nonatum. However, recent research shows these ciliates to be identical to the same ciliates associated with WS in both aquaria and in the wild (Philaster sp.) and closely related to ciliates associated with another wild disease called Brown Band Disease (BrB) which has been associated with Philaster guamensis

While ciliates are undisputedly present in the brown jelly material associated with BJS, it remains unclear as to what exact role they play in the disease pathology (i.e. are they the primary causal agents or secondary invaders?). This is also the case for the wild type disease BrB. It is feasible they are only present because they are feeding on dead tissue arising from another pathogen or non-pathogenic disease (Borneman & Lowrie, 2001). In support of this, the Zoological Society of London (ZSL) has often but not always isolated Vibrio spp. particularly V. vulnificus from corals such as Goniopora and Euphyllia exhibiting disease signs similar to BJS (Pers obs), however further work needs to be conducted. 

Management or Mitigation:

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As with WS, the use of a broad-spectrum antibiotic, such as chloramphenicol (Tifomycine:flexyx.com, only available in USA) and metronidazole is commonly cited. Doxycycline, Oxytetracycline, Iodine and freshwater dips (15 ppt) have all been used. Low salinity should only be used for large polyp species, smaller polyp species such as Acropora do not tolerate low salinity well particularly when they are already stressed by disease. Removing infected areas of a colony well ahead of the line of healthy tissue can sometimes stop the infection from spreading but great care should be taken to siphon off loose tissue first and avoid spreading infected material around the tank. Isolation of any samples showing this disease have also been reported to sometimes stop the spread to other corals. 

Brown Band Disease: 

A similar disease, often found in the wild is called Brown Band Disease. Recently studies have proven that ciliates like those reported on here associated with both White Syndrome and Brown Jelly Syndrome are indeed the causal agents and often follow after damage to the coral tissue. Below is the abstract of the recent publication by Stefano Katz from Jame Cook University in Australia. 

Brown band (BrB) disease manifests on corals as a ciliate-dominated lesion that typically progresses rapidly causing extensive mortality, but it is unclear whether the dominant ciliatePorpostoma guamense is a primary or an opportunistic pathogen, the latter taking advantage of compromised coral tissue or depressed host resistance. In this study, manipulative aquarium-based experiments were used to investigate the role of P. guamense as a pathogen when inoculated onto fragments of the coral Acropora hyacinthus that were either healthy, preyed on by Acanthaster planci (crown-of-thorns starfish; COTS), or experimentally injured. Following ciliate inoculation, BrB lesions developed on all of COTS-predated fragments (n = 9 fragments) and progressed up to 4.6 ± 0.3 cm d−1, resulting in ~70 % of coral tissue loss after 4 d. Similarly, BrB lesions developed rapidly on experimentally injured corals and ~38 % of coral tissue area was lost 60 h after inoculation. In contrast, no BrB lesions were observed on healthy corals following experimental inoculations. A choice experiment demonstrated that ciliates are strongly attracted to physically injured corals, with over 55 % of inoculated ciliates migrating to injured corals and forming distinct lesions, whereas ciliates did not migrate to healthy corals. Our results indicate that ciliates characteristic of BrB disease are opportunistic pathogens that rapidly migrate to and colonise compromised coral tissue, leading to rapid coral mortality, particularly following predation or injury. Predicted increases in tropical storms, cyclones, and COTS outbreaks are likely to increase the incidence of coral injury in the near future, promoting BrB disease and further contributing to declines in coral cover.

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After treatment

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After treatment of corals suffering from BJS with Metronidazole (by Dr William Wildgoose), the ciliate's were observed to die off and be completely absent (see picture of brown jelly with no ciliate's present). If the corals survive remains to be known, it is likely treatment such as this will work if you catch the disease early enough. If the coral is to far gone and the disease to wide spread fragmentation and isolation are still the best bet. 



Red Slime Algae or Red Band Disease

Background:

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This disease falls under the broad spectrum of cyanobacterial overgrowth forming a mat over the aquarium floor and often the corals themselves. It varys in colour from red, black to blue-green. There are strong similarities between this disease morphology and that of the cyanobacterial mat of Black Band Disease within wild coral populations (Weil, 2004; Weil & Croquer, 2009).

Causes:

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This disease is most commonly associated with high levels of organic nutrients within the aquarium, which in turn may be influenced by changes in light levels. Despite the common name of this disease, the causal agent is not actually an alga at all, but a consortium of cyanobacteria (photosynthetic filamentous bacteria).

Management or Mitigation:

Picture Red Slime Algae is reported to be treatable by commercial products such as Ultralife Red Slime Remover, Boyd Chemi-Clean, and Blue Life Red Slime Control (Brang, 2010). However, many of these diseases are reported as a sign of poor water quality, so most aquarists propose reassessment and improvement of aquarium water quality (reducing levels of nitrate and phosphate and monitoring light levels and improving flow) as the most effective treatment. Because the cyanobacteria are photosynthetic, masking the band with putty or plasticine has been reported to be effective in the wild.

Snails

Background:

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There are a few coral-eating snails commonly appearing in aquariums. Most prey on soft corals.  Depending on the snail species, number of snails and the corals involved, predation can range in severity from hardly noticeable to devastating. 

Causes:

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The most common corallivorous snails your likely to encounter are Drupella, Heliacus and Coralliophila

Heliacus - Also known as Box snails. These snails are notorious for feeding on Zoanthids.  They have a classic shaped shell that is round at the base and twists upward into a point. Usually smaller than a pea. Tan and brown colouration alternate within the striations of the shell, giving it a rather beautiful appearance. They may or may not become a problem. The Box Snails are guilty of consuming many different types of polyps within the ZoanthusPalythoa and Protopalythoa genera. Many times the snail will be found within the colony itself, where they puncture the base of the polyp, and feed upon its tissue and fluids. The polyp is then basically left as an empty shell, which quickly falls off of the rock and decomposes. Drupella cornus, commonly known as the horn drupe has a shell size of an adult between 28 - 40 mm. This whitish shell shows four rows of spiny, pointed nodules with numerous smaller spines between. They lay benthic egg capsules, which hatch into free-swimming planktonic larvae. This particular  snail is attracted to Montipora corals
Coralliophila abbreviata
is known to affect corals in the wild and within aquaria, this particular species is commonly associated with Montastraea sp. and Acropora sp.  

Management or Mitigation:

Picture Quarantine of the coral and manual removal of the snails is the best treatment (if the snails become a problem).  

Red Bugs

Background:

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Infestations from the 'red bug' Tegastes acroporanus is often referred to as a disease/syndrome in most of the grey literature. T. acroporanus is a predatory micro-crustacean which is specific to acroporids, they are small, ca. 0.5 mm in length and yellow in colour with a distinctive red dot which gives this species its common name. Poor polyp extension, loss of colouration and overall decline in health have been reported as signs of infection. Infestations of T. acroporanus have so far not been recorded in the wild to date, although would be easily overlooked due to their size. 

Causes:

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As the name suggests, this is caused by large numbers of T. acroporanus. As this parasite is now widely distributed in the marine aquarium industry it is easily transferred between aquaria by the exchange of cultivated colonies. Great care should be taken when receiving Acropora colonies from another collection to quarantine them before introducing them to aquariums with existing Acropora spp. The quarantine period should involve close observations preferably with a magnifying lens to look specifically for this invertebrate

Management or Mitigation:

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A treatment of red bug disease caused by T. acroporanus, first developed by Dorton (2010), is the use of Milbemycin oxime, an active ingredient in heart worm medication for dogs called “Interceptor” within the USA or in a product called ‘Milbemax’ in the UK (where M. oxime is mixed with Praziquantal). This is an indiscriminate drug which kills all crustaceans as well as T. acroporanus, so would not be a feasible treatment of wild diseases or aquaria with mixed communities including crustaceans (crabs, lobsters, shrimp). An attractive option to this treatment is the introduction of a biological control, the dragonface pipefish, Corythoichthys haematopterus for example. These fish are known to anchor themselves to Acroporids and feed on crustaceans including T. acroporanus. It is also common that secondary infections often follow, initiating from the feeding scars caused by T. acroporanus, along with the scars left by nudibranchs, Drupella and/or other corallivorous snails. 

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Acropora Eating Flatworms

Background:

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Adult (white arrow) with feeding scars (black arrows)

The Acropora-eating flatworm (AEF or AEFW) is a common predator of aquarium Acropora species.They consume coral tissue and are extremely well-camouflaged. On first glance, the only visible sign of their presence is feeding scars, which expose the coral skeleton.  Feeding lesions may be misdiagnosed as other syndromes (potentially classed in the WS group), and so the impact of this predator in the wild is not fully appreciated. 

Causes:

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Although a problematic Acropora predator in aquaria for over 10 years, very little was known about the AEFW, it's biology or taxonomic affinity until last year when it was named Amakusaplana acroporae (a polyclad worm belonging to the phylum Platyhelminthes) and information on its life history was described (Rawlinson et al. 2011). As this parasite is now widely distributed in the marine aquarium industry it is easily transferred between aquaria by the exchange of cultivated colonies. Great care should be taken when receiving Acropora colonies from another collection to quarantine them before introducing them to aquaria with existing Acropora spp. The quarantine period should involve close observations to look specifically for this small flatworm (adult size: ~ 1cm), it's feeding scars and egg batches which are laid on the bare coral skeleton.

Management or Mitigation:

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Eggs batches on coral skeleton (photo by J. Weatherson)

For the treatment of flatworm infections, including the AEFW, Salifert’s Flatworm Exit, levamisole hydrochloride, freshwater dips (15 ppt for 3 m max) and iodine-based dips like Lugols iodine, Fluke-Tabs (Aquarium Products), and Trichlorfon (Dylox 80, Bayer A.G.) have all been reported for treatment of infected corals (Carl 2008; Nosratpour 2008). However, it is important to note that smaller polyp species such as the Acroporids can rarely tolerate the use of freshwater dips and often mortality occurs soon after treatment. 

FlatwormStop is a new treatment from Zeovit which allows direct dosing of a full stocked reef aquariums. FlatwormStop is safe for all fish and invertebrates and it works to eradicate Acro Eating Flatworms by stimulating the immune response of Acropora corals.




Below is one Hobbyist Procedure for eradication of these pests. 

1. Remove all Acropora corals from rocks including encrusted ones and scrape off encrusted left over coral parts on the rocks. Inspect each coral with a flashlight for 2 minutes outside of tank and water (a bit of air drying allows eggs to be easier to identify) and scrape any off eggs. Might be beneficial to cut the base off certain heavily infested corals and through out a others which have to many eggs.

2. Dip in diluted Revive solution (according to instructions) for 8-10 minutes for hardy Acroporas but 5 minutes for deep water Acroporas and other sensitive corals. Swirl corals initially in Revive solution then blast them with a turkey baster 5-10 times while dipping.


Be careful with deep water Acropora corals and others.  Pearlberry, Ice Fire, and Hawkins Eechidna corals are especially sensitive as you can blast the skin off of them if you are too harsh.


3. Swirl and let sit in fresh saltwater after Revive dip for 10 minutes. Blast with turkey baster 3-4 times every few minutes. Return to tank but on sand bed.


4. Repeat weekly for 2 additional weeks.


5. Glue corals to small rock bases and reattach to live rock. Now check periodically for re infestation e.g. bitemarks and AEFW’s that may come off by blasting, etc. Use common sense.


6. Add a natural predator or two; e.g. Yellow Wrasse, scientific name Halichoeres chrysus, to form a biological AEFW control team with others such as the Six Line Wrasse. These guys like to eat a variety of small pests from corals.




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Photo of live Amakusaplana acroporae hatchling



Preventing Coral Diseases

Prevention is mainly down to ensuring good water quality at all times, as well as maintaining coral safety (from fish bites, falls and stings from other corals) and clean corals (good water flow). Also ensuring standardised temperatures and ultraviolet radiation. The need for good quarantine procedures is important particularly if you donate or receive colonies to or from other collections. It is important to have a good idea of the potential pests and parasites to look out for but it is also necessary to keep an open mind as there is always the chance of something completely new appearing. If a novel parasite is suspected taking pictures of it on the coral and of any damage it has done to the coral's tissue is helpful. Preserving a sample of any suspected parasite in ethanol can also help with identification but good notes about where and when it was found, and on what species of coral is also important.



GREAT Preventative/precautionary measures



Freshwater Dip (for saltwater fish only)

The freshwater dip is probably the most common dip for saltwater species and will rid the fish’s body of many potential harmful parasites.
Parasites such as:
  • Paravortex (the black spot disease a.k.a. black ick) which is caused by the turbellarian flatworm with a similar life cycle as “Ick”
  • Cryptocaryon which is the marine equivalent to “ick” a.k.a. marine or saltwater “ick”
  • Velvet or coral fish disease (similar life cycle as “Ick”) is difficult to diagnose due to a similar Ick-infested fish behavior, as well as the undetectable and highly infectious skin flukes (worms living on the fish).
Saltwater species have a constant exchange of fluids called osmosis, which in simple terms is when pure water dilutes the mineral and salt rich water in order to equalize. Freshwater will rupture the cells of the parasites instantly killing them in great numbers independently of the status of the reproductive cycle. (i.e. ick medications are only effective on the free-floating tomites).
The freshwater dip is very effective to rid the fish of parasites causing black ick, marine ick, velvet and flukes, but ineffective towards bacterial or fungal diseases.
The bath has to be prepared with pure water, preferably RO/DI, or as an alternative distilled water. The fish should be closely watched and the bath administered for 5-10 minutes.

Saltwater Dip (for freshwater fish only)

Fish stress is relieved and the organism can fight off diseases easier which aides in the recovery. The concentration should be 4 teaspoons per Gallon and the duration of the bath about 30 minutes. This bath will also stimulate the protective slime coat, which will further enhance the fish’s’ ability to cope with the disease.
Protozoa (one celled parasites) on skin, gills, and fins can effectively be removed by a salt bath. For the record, some fish do not respond well to a salt bath (i.e. some barbs, tetras, catfish and koi). A heavy concentration can make them loose their equilibrium and they simply “roll over”. At this point the fish has to be moved to clear water very quickly.

Formalin Bath

Formalin (formaldehyde gas dissolved in water) is used as a bath to rid external parasites. Formalin works by altering cell proteins.
Formalin is often used with Malachite Green, but should not be used in combination with any other medication. Extreme caution is necessary as Formalin depletes oxygen. The container used for the bath has to be continuously well oxygenated. Formalin will effect the biological filter and should never be introduced to the main aquarium.
The bath should consist of 250mg/l for about 60 minutes. Extremely sick or weak fish should be removed after 30 minutes. In warmer water (above 70F/21 C) 150 mg/L should be used for no longer then 60 minutes.

Malachite Green

This compound rids the fish of all fungal infections. Malachite green is a respiratory poison and damages the cell metabolism. Rarely used by itself, the bath should contain 1-2 mg/l for 10 minutes, or 0.5 mg/l for up to 1 hour.
Malachite Green will turn colorless at higher pH levels, but that does not mean that it lost its potency.
Light will deactivate this compound either if used by itself or in combination with other medications, light should therefore be kept at a minimum.

Formalin and Malachite Green

Both compounds are often used in combination because both increase the benefits of each other. They are also less toxic as if used separately.
Malachite green as well as Formalin can use up their oxidizing characteristics on dissolved organics rather then on the disease causing organisms. To avoid this and to ensure proper application, it is essential to use distilled or RO/DI water.
Both compounds are more toxic in lower pH concentrations vs. higher levels.

Methylene Blue

Methylene Blue is effective against skin and gill flukes, ick, velvet, fungus and many external parasites and bacterial infections. This compound is very safe to use even for many invertebrates. Methylene Blue works by staining cells and disabling their metabolism.
A positive side effect of this compound is the ability to increase hemoglobin (oxygen carrying cells) by transforming methemoglobin. Because of this characteristic, methylene blue can be used to treat nitrite and cyanide poisoning.
Methylene Blue should not be used in the main aquarium as it will destroy or severely defect the biological filter bacteria. It can also permanently discolor equipment and silicate seals blue.
About 12 mg/l will treat a saltwater fish for up to one hour and a freshwater fish for up to 10 minutes. A dip can be as high as 50 mg/l for duration of 10 seconds.

Potassium Permanganate

Permanganate will eliminate anchor worms, fish lice, flukes, ick, cotton mouth, fungus and many bacteria.
The bath containing permanganate should be prepared in distilled water, because a presence of organic matter will lower its efficiency. Potassium Permanganate is an oxidant and waste particles will use up the oxidative energy before potential parasites/bacteria will be affected.
The bath is prepared in a ratio of 2 mg/l for up to 4 hours or 10 mg/L for up to 30 minutes. During the treatment time the solution has to retain the purple discoloration, more permanganate can be added should the discoloration fade before the end of the required treatment time.
Fish should be closely monitored. In case of an overdose, potassium permanganate can be deactivated by an equal amount of hydrogen peroxide. In severe cases, a dip in pure milk will remove all traces of that chemical.

Preparing the new Fish for the bath/dip

Before any dip or bath is applied, the new fish should be acclimated to the new environment (aquarium). This is best done by placing the bag onto the water surface in the aquarium and left afloat for 15 minutes. This will acclimate the fish to the water temperature. About one half of the bags water volume should be added using water from the main tank (i.e. if the bag holds 4 cups of water add 2 cups from the aquarium into the bag).
Repeat adding water for 2-3 times with a 5 minute resting period in-between. This will acclimate the fish to the present water conditions (i.e. pH and salinity for marine aquariums).
In preparation of the dip, use only distilled or RO/DI water. Prepare the solution according to the directions included in the packaging.
Use the water in the bag for the after treatment period. This will help dilute any residues before being released into the main aquarium. It will be sufficient to keep the fish in the “bag” for about 5 minutes before releasing it into the aquarium.
Fish dips should only be used for new arrivals and when required due to fish disease.

Vitamin C

When treating an aquarium on a preventive basis (against diseases in general), it is not necessary to add large dosages of Vitamin C. All we are trying to achieve is provide the corals with a constant low supply of Vitamin C to build up their immune system and take advantage of the other benefits offered by this vitamin.

Add the vitamin for a period of 14 days to 1 month and then stop adding for 2 to 3 months, resuming the treatment again the following month (hence treat for 14-31 days every 3 to 4 months). Treating with Vitamin C requires that you pay close attention to the pH all the time. When dosing Vitamin C for the home aquarium, the preferred product is Sodium Ascorbate powder. This form of vitamin C has been buffered to be of a neutral pH and is less likely to have adverse side effects on a reef aquarium. Dosage is usually done in the 5-30 parts per million (milligrams per liter) range with variance depending on the desired effect of dosing.

Benefits: 

> Builds up and strengthens the immune system.
> Helps prevent bacterial infections from spreading rapidly.
> Aid healing in coral wounds
> Eliminates minor algae outbreaks
> Helps clean up the water
> Safe for use in all aquariums, including reefs (many other medications are not) 

Tank Parameters

Parameter                                  Range              Frequency of testing

Temperature                              25-27oC                         Daily
pH                                               8-8.4                             Daily
Salinity                                      33-35ppt                         Daily
Ammonia                                NH4 <0.1ppm                  Weekly
Nitrite                                     NO2 <0.1ppm                   Weekly
Nitrate                                     NO3 <5ppm                     Weekly
Phosphate                              PO4 <0.1ppm                    Weekly
Calcium                                 Ca 380-500ppm                 Weekly
Alkalinity                                   2.5-4 meq/l
                                                  7-11 dKH
                                                125-200ppm                     Weekly
Magnesium                          Mg 1250-1350ppm              Monthly


This is a website that is VERY helpful in diagnosing various coral diseases by region the corals originate from.


Diseases by Region

Wednesday, October 22, 2014

Is Aqua Farming the Answer? Is it Healthier?

Aqua Farming
Many folks think that aqua farming is a great alternative than scouring the seas to find the freshest catch or perhaps that perfect coral. As far back as 6000 B.C. humans have been cultivating ways to extend the life or produce more immediate results with less work at obtaining aquatic life for human consumption and or pleasure. It was not until the mid 1970's that aqua farming versus wild caught really took off.

More than 50% of fish or crustaceans are bred to provide food for human consumption. Aquaculture is one of the most resource-efficient ways to produce protein. Fish come out well because, in general, they convert more of the food they eat into body mass than land animals.  “Feed Conversion Ratios” indicate how many pounds of feed it takes to produce a pound of protein. As can be seen in the table below, salmon – the most feed-intensive farmed fish – is still far more efficient than other forms of protein production.

Protein
Feed Conversion Ratio
Salmon
1.2
It takes 1.2 pounds of feed to produce 1 pound of salmon
Beef
8.7
It takes 8.7 pounds of feed to produce 1 pound of beef
Pork
5.9
It takes 5.9 pounds of feed to produce 1 pound of pork
Chicken
1.9
It takes 1.9 pounds of feed to produce 1 pound of chicken

There have been controversy on whether or not aqua farming is safe. NOAA states that yes it is, the U.S. laws governing the harvest and processing of seafood for human consumption are among the most stringent in the world. The responsibilities of monitoring and controlling seafood safety are divided among various agencies of the federal government and individual states. The primary federal agencies involved with seafood safety include:
Consumers play an important role in seafood safety as well. When shopping for seafood, it is important to know what to look for. Read the NOAA Fishwatch Program ‘Seafood & Your Health, page for information about buying, handling, storing, and cooking seafood.

CNN wrote an article here describing whether or not wild caught or farmed fish were healthier,   Farmed or Wild Caught?

Organizations such as People of the Ethical Treatment of Animals or PETA, for short, have their own opinions and offer a point of view on a completely different side of this discussion.   

PETA states, More than 40 percent of all the fish consumed each year are now raised on land-based or ocean-based aquafarms where fish spend their entire lives in cramped, filthy enclosures and where many suffer from parasitic infections, diseases, and debilitating injuries.
The United Nations’ Food and Agriculture Organization reports that the aquaculture industry is growing three times faster than land-based animal agriculture, and aquafarms will surely become even more prevalent as our natural fisheries become exhausted.
On aquafarms, high-volume systems control food, light (on indoor farms), and growth stimulation. Drugs and genetic engineering are used to accelerate growth and change reproductive behaviors.

Injuries and Death

In intensively crowded aquafarms, small fish are bullied and killed by larger fish, so fish are continually sorted to make sure that faster-growing individuals are moved to the appropriate size grouping.
At each sorting, they are netted or pumped out of their tanks and dumped onto a series of bars and grates with varying space gaps to divide them by size and redistribute them into different netted cages or tanks; small fish slip through the small grates while larger fish fall through the larger gaps. This practice, called “grading,” is very stressful and results in painful scrapes and a loss of protective scales, leaving the animals vulnerable to disease.
High mortality rates, disease, and parasite infestations are common. Deformities and stress-related injuries are also a regular occurrence; on some farms, as many as 40 percent of the fish are blind—a problem that is not addressed because blind fish net the same profit for farmers.

Crowding

Because they are designed to navigate vast oceans and use all their senses to do so, many fish go insane from the cramped conditions and lack of space on fish farms. The tight enclosures inhibit their ability to navigate properly and cause them to knock against each other and the sides of the enclosures. This jostling causes sores and damage to their fins.
To increase profits, fish farmers cram as many fish as possible into the smallest spaces possible. Salmon farms are so crowded—with as many as 50,000 individuals in each enclosure—that a 2.5-foot fish spends his or her entire life in a space the size of a bathtub. Trout farms are even more crowded, with as many as 27 full-grown fish in a bathtub-sized space.

Fish Feed

Many species of farmed fish are carnivorous, which means that fish must be caught from our already-exhausted oceans to feed the fish on aquafarms. It can take more than 5 pounds of fish from the ocean to produce just 1 pound of farmed salmon or sea bass. Aquafarmers have even begun to feed fish oil and fish meal to fish who naturally eat only plants in an effort to make them grow faster.
What’s more, fish farmers lace fish feed with powerful chemicals and antibiotics to help fish survive the deadly diseases caused by the crowding and filth. It’s likely that these fish pellets are the cause of the higher PCB and dioxin contamination levels found in farmed fish, which are seven times higher than the already-dangerous levels found in their wild counterparts.

Contaminant Stew

Contaminants from ocean-based aquafarms (fish excrement, uneaten chemical-laden food, and swarms of parasites) spread to the surrounding ocean, and the rampant disease inside the cages is passed on to ocean fish in the area, in some cases increasing the incidence of sea lice a thousandfold.
These parasites eat at the fish, causing their scales to fall off and creating large sores. In severely crowded conditions, lice often eat down to the bone on fish’s faces. This is so common that fish farmers have taken to calling it the “death crown.”

Fish Slaughter: Unregulated Suffering

In the United States, there are no regulations to ensure the humane treatment of fish.



As many as 40 percent of farmed fish die before the aquafarm operator is ready to slaughter them. Fish who survive are starved before they are sent to slaughter in order to reduce waste contamination of the water during transport. Salmon, for example, are starved for 10 full days.
Fish slaughter plants in the U.S. make no effort to stun the fish, who are completely conscious when they start down the slaughter line. Their gills are cut, and they are left to bleed to death, convulsing in pain.
Large fish, such as salmon, are sometimes bashed on the head with a wooden bat called a “priest,” and many are seriously injured but still alive and suffering when they are cut open. Smaller fish, such as trout, are often killed by simply draining water away and leaving them to slowly suffocate or by packing them in ice while they are still completely conscious.
Because fish are coldblooded, allowing them to suffocate on ice prolongs their suffering, leaving them to experience excruciating pain for as long as 15 minutes before they die.
Im not looking to hear an opinion for this discussion, I just want to throw some "food" out there for thought, on all sides with regards to saving and preserving our oceans life and the responsibilities for those that provide ways of doing that.  

Is Aqua Farming the Answer? Is it Healthier?

Aqua Farming
Many folks think that aqua farming is a great alternative than scouring the seas to find the freshest catch or perhaps that perfect coral. As far back as 6000 B.C. humans have been cultivating ways to extend the life or produce more immediate results with less work at obtaining aquatic life for human consumption and or pleasure. It was not until the mid 1970's that aqua farming versus wild caught really took off.

More than 50% of fish or crustaceans are bred to provide food for human consumption. Aquaculture is one of the most resource-efficient ways to produce protein. Fish come out well because, in general, they convert more of the food they eat into body mass than land animals.  “Feed Conversion Ratios” indicate how many pounds of feed it takes to produce a pound of protein. As can be seen in the table below, salmon – the most feed-intensive farmed fish – is still far more efficient than other forms of protein production.

Protein
Feed Conversion Ratio
Salmon
1.2
It takes 1.2 pounds of feed to produce 1 pound of salmon
Beef
8.7
It takes 8.7 pounds of feed to produce 1 pound of beef
Pork
5.9
It takes 5.9 pounds of feed to produce 1 pound of pork
Chicken
1.9
It takes 1.9 pounds of feed to produce 1 pound of chicken

There have been controversy on whether or not aqua farming is safe. NOAA states that yes it is, the U.S. laws governing the harvest and processing of seafood for human consumption are among the most stringent in the world. The responsibilities of monitoring and controlling seafood safety are divided among various agencies of the federal government and individual states. The primary federal agencies involved with seafood safety include:
Consumers play an important role in seafood safety as well. When shopping for seafood, it is important to know what to look for. Read the NOAA Fishwatch Program ‘Seafood & Your Health, page for information about buying, handling, storing, and cooking seafood.

CNN wrote an article here describing whether or not wild caught or farmed fish were healthier,   Farmed or Wild Caught?

Organizations such as People of the Ethical Treatment of Animals or PETA, for short, have their own opinions and offer a point of view on a completely different side of this discussion.   

PETA states, More than 40 percent of all the fish consumed each year are now raised on land-based or ocean-based aquafarms where fish spend their entire lives in cramped, filthy enclosures and where many suffer from parasitic infections, diseases, and debilitating injuries.
The United Nations’ Food and Agriculture Organization reports that the aquaculture industry is growing three times faster than land-based animal agriculture, and aquafarms will surely become even more prevalent as our natural fisheries become exhausted.
On aquafarms, high-volume systems control food, light (on indoor farms), and growth stimulation. Drugs and genetic engineering are used to accelerate growth and change reproductive behaviors.

Injuries and Death

In intensively crowded aquafarms, small fish are bullied and killed by larger fish, so fish are continually sorted to make sure that faster-growing individuals are moved to the appropriate size grouping.
At each sorting, they are netted or pumped out of their tanks and dumped onto a series of bars and grates with varying space gaps to divide them by size and redistribute them into different netted cages or tanks; small fish slip through the small grates while larger fish fall through the larger gaps. This practice, called “grading,” is very stressful and results in painful scrapes and a loss of protective scales, leaving the animals vulnerable to disease.
High mortality rates, disease, and parasite infestations are common. Deformities and stress-related injuries are also a regular occurrence; on some farms, as many as 40 percent of the fish are blind—a problem that is not addressed because blind fish net the same profit for farmers.

Crowding

Because they are designed to navigate vast oceans and use all their senses to do so, many fish go insane from the cramped conditions and lack of space on fish farms. The tight enclosures inhibit their ability to navigate properly and cause them to knock against each other and the sides of the enclosures. This jostling causes sores and damage to their fins.
To increase profits, fish farmers cram as many fish as possible into the smallest spaces possible. Salmon farms are so crowded—with as many as 50,000 individuals in each enclosure—that a 2.5-foot fish spends his or her entire life in a space the size of a bathtub. Trout farms are even more crowded, with as many as 27 full-grown fish in a bathtub-sized space.

Fish Feed

Many species of farmed fish are carnivorous, which means that fish must be caught from our already-exhausted oceans to feed the fish on aquafarms. It can take more than 5 pounds of fish from the ocean to produce just 1 pound of farmed salmon or sea bass. Aquafarmers have even begun to feed fish oil and fish meal to fish who naturally eat only plants in an effort to make them grow faster.
What’s more, fish farmers lace fish feed with powerful chemicals and antibiotics to help fish survive the deadly diseases caused by the crowding and filth. It’s likely that these fish pellets are the cause of the higher PCB and dioxin contamination levels found in farmed fish, which are seven times higher than the already-dangerous levels found in their wild counterparts.

Contaminant Stew

Contaminants from ocean-based aquafarms (fish excrement, uneaten chemical-laden food, and swarms of parasites) spread to the surrounding ocean, and the rampant disease inside the cages is passed on to ocean fish in the area, in some cases increasing the incidence of sea lice a thousandfold.
These parasites eat at the fish, causing their scales to fall off and creating large sores. In severely crowded conditions, lice often eat down to the bone on fish’s faces. This is so common that fish farmers have taken to calling it the “death crown.”

Fish Slaughter: Unregulated Suffering

In the United States, there are no regulations to ensure the humane treatment of fish.



As many as 40 percent of farmed fish die before the aquafarm operator is ready to slaughter them. Fish who survive are starved before they are sent to slaughter in order to reduce waste contamination of the water during transport. Salmon, for example, are starved for 10 full days.
Fish slaughter plants in the U.S. make no effort to stun the fish, who are completely conscious when they start down the slaughter line. Their gills are cut, and they are left to bleed to death, convulsing in pain.
Large fish, such as salmon, are sometimes bashed on the head with a wooden bat called a “priest,” and many are seriously injured but still alive and suffering when they are cut open. Smaller fish, such as trout, are often killed by simply draining water away and leaving them to slowly suffocate or by packing them in ice while they are still completely conscious.
Because fish are coldblooded, allowing them to suffocate on ice prolongs their suffering, leaving them to experience excruciating pain for as long as 15 minutes before they die.
Im not looking to hear an opinion for this discussion, I just want to throw some "food" out there for thought, on all sides with regards to saving and preserving our oceans life and the responsibilities for those that provide ways of doing that.