Varroosis Disease of Honey Bees
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Varroosis disease is an enormous threat to honey bee colonies. Understanding and managing this disease is very necessary for every beekeeper. Let's grab some know-how about Varroosis. You'll learn how to protect your hives and increase honey production.
What is Varroosis?
Folks consider Varroa destructor a main factor in Varroosis disease.
The female Varroa mite is oval, brown, about 1.17 mm long and 1.77 mm wide;
The male is slightly smaller, oval, about 0.88 mm long and 0.72 mm wide.
Most adult mites parasitize between the abdomen segments of worker bees and drones. They suck body fluids from adult bees.
Female Varroa mites will sneak into brood cells to lay eggs, causing bee larvae to develop poorly. They weaken your bee colony at the source. They endanger honeybee populations
You can picture what it would look like if varroa mites severely attacked a bee colony. If you have trypophobia, you would feel gross! You may find more than 20 mites on a single drone pupa and up to 12 on a worker bee.
Varroa mites are vectors for harmful viruses, including those that cause foulbrood and spore diseases. Even though we use miticides, honey bee virus levels remain high.
This disease endangers honey bee populations. In the worst case, they can cause colony collapse, which messes with agricultural production.

History and Origin
Discovery of Varroa Mites
Researchers first identified Varroa in Southeast Asia in the early 20th century. These beekeeping pests first infested the Asian honeybee, Apis cerana. In the 1960s, they began infecting European honeybees (Apis mellifera), spreading rapidly worldwide. This spread was largely because of the movement of infested bees and beekeeping equipment.
Impact on Beekeeping Industry
In the early stages of attempting to manage this parasite problem, beekeepers employed chemical treatments, specifically Amitraz, a miticide. Nonetheless, their widespread presence and survival ability have caused enormous problems. Beekeepers had to accept that Varroosis was a constant problem. We cannot easily eradicate Varroa mites.
Over time, Varroa mites have greatly changed how we treat bees. We use chemicals, breed bees to resist mites, and improve how we manage hives.
Researchers focus on boosting honeybees' natural defenses by selectively breeding them and finding non-chemical ways to control.
Varroa Mite Biology
Varroa Mite Life Habits:
Varroa mites can only reproduce within sealed brood cells. Their development cycle includes three stages: egg, nymph, and adult mite. They primarily infest bee bodies and brood cells.
When spring comes, the bee colony has capped brood combs. Those annoying mites start reproducing. As the number of brood cells goes up, more Varroa mites infest them. The infestation hits its highest point in the summer.
In the fall, as the honeybee colony's population declines, the number of brood cells decreases. Varroa mites continue to reproduce, shifting towards infesting a smaller number of cells and adult bees.
By the winter, Varroa mites cease reproduction and remain in the adult stage. They feed on bees' bodily fluids by overwintering with honeybees. That is to say, they can harm bee colonies throughout the entire year.
Varroa Mite Activity:
Temperature influences Varroa mite activity. In winter, bees must maintain a stable temperature within the beehive to ensure survival. This temperature also meets its survival requirements, but not its egg-laying requirements.
Varroa mites become active with temperatures above 18°C. To breed normally, they need temperatures reaching around 31°C. They are unable to reproduce in a broodless bee colony during winter. However, they can still coexist with honeybees during the winter.

Varroosis Symptoms and Diagnosis
Visible Signs in Bee Colonies
Observe the Head: Healthy bees exhibit lively, natural head movements. They give us a cute impression. If their head movements appear stiff or itchy, it may be a sign of infestation.
Observe Wings and Legs: Healthy bees have intact wings, spread their wings easily, and fly quickly. If you find young bees with damaged wings crawling on the ground, they cannot fly. This is Varroosis.
Diagnostic Methods
Mite Level Evaluation: Beekeepers should adhere to the principle of "prevention-oriented, integrated treatment." First, you need to analyze the severity of bee mite infestation.
Regular monitoring helps you to judge whether your bee colonies have reached a threshold that requires Varroosis control. Beekeepers can use several methods to estimate mite infestation levels, for example:
- Sugar Roll: Dust sample bees with powdered sugar in a Varroa tester jar. Shake the jar, causing mites to fall off. Then we can count sugar-coated mites.
- Alcohol Wash: You will also need a Varroa tester jar. Take some sample bees and submerge them in alcohol. Varroa mites will sink to the bottom of the solution, and then you can begin counting. This simple detection is the most accurate of all.
- Sticky Boards: A Varroa board has a sticky substance below a screened bottom. Placed under a beehive, these boards catch falling mites. This method only roughly monitors an infestation rate because it does not take the honeybees' population into account.
After completing an assessment of your bee colonies, you must master when to treat Varroa mites. This will allow you to save your colony at the optimal time.
Threats to Bee Colony Health
Physical Harm: Varroa mites primarily feed by sucking hemolymph and bodily fluids from the surface of honeybees. They deprive bees of necessary nutrients. This makes them weak, slows their growth, and even causes them to die early.
Infested honey bee larvae may experience stunted development, resulting in weight loss and deformed wings or legs. They may also lose the ability to fly.
Transmission of Viruses: Varroa mites are vectors for several harmful viruses. Deformed Wing Virus (DWV) and Acute Bee Paralysis Virus (ABPV), etc., are examples. Varroa-infested colonies transmit viruses through their saliva.
These viruses can disrupt the immune system of bees, which makes them physically weaker. This heightened risk makes it easier for them to contract secondary infections and diseases.

Management and Control Strategies
In beekeeping, Varroa mite treatments are often not singular. Treatments typically involve alternating multiple methods.
Common Acaricides: Regular substances such as amitraz, fluvalinate, coumaphos, etc. are chemical treatments.
Organic Miticides: Mild chemical substances include oxalic acid, formic acid, thymol, etc. In the beekeeping industry, we regard these products as organic medication.
Pros and Cons:
Chemical treatments exhibit efficacy in diminishing mite numbers. Nevertheless, these treatments also possess certain drawbacks.
One drawback is that they may develop resistance if you don't follow usage instructions. Another issue is that chemicals have potential harm to bees. Additionally, there is a risk of pollution of hive products.
Organic acaricides are generally safer for the environment and bee products. However, applying organic treatments often requires large doses. This means more labor with careful handling. Moreover, they may not be as effective as synthetic chemicals.
Non-Chemical Methods
Mechanical Controls: Techniques such as drone brood removal (where drone brood, which attracts more mites, is removed or destroyed). Using screened bottom boards to trap falling mites can help reduce their populations.
Biological Controls: Breeding mite-resistant bee strains is a trending research direction in recent years. Using organisms that hunt Varroa mites offers a promising non-chemical method.
Challenges and Future Directions
Resistance to Treatments
Development of Acaricide Resistance: Overuse of chemical treatments has led to resistant mite populations. These treatments become less effective.
Need for New Control Methods: Research into innovative hive management strategies is a constant need.
Innovations in Research
Some points of view are around sustainable beekeeping. The biological method of artificial brood interruption, when combined with treatment, offers the highest level of control, effectively limiting Varroa population growth. Methods such as queen caging, drone brood removal, total brood removal, and trapping comb are used in this approach.

Additional Resources
Links to Further Reading
Scientific Articles and Studies: If you want the latest research on Varroa mites and control methods, refer to [NCBI].
Beekeeping Forums and Support Groups: Resources for beekeepers seeking advice and community support, like [BeeSource]
Practical Guides and Tutorials
Videos and Online Courses: Visual and interactive resources for learning about Varroa management, available on [Honey Bee Health Coalition]