100 Examples of sentences containing the common noun "iridophores"

Definition

Iridophores are specialized cells found in the skin of certain animals, notably some fish, reptiles, and cephalopods. These cells contain iridophores, which reflect light and produce iridescent colors, contributing to the organism's coloration and ability to camouflage or communicate.

Synonyms

Iridescent cells
Reflective chromatophores

Antonyms

Melanophores (cells that contain dark pigments)
Erythrophores (cells that contain red pigments)

Examples

The cuttlefish uses iridophores to change its color rapidly.
Some species of fish can manipulate their iridophores for better camouflage.
Researchers study how iridophores function in different aquatic environments.
The presence of iridophores gives certain reptiles their vibrant appearance.
Iridophores play a crucial role in the signaling mechanisms of some animals.
The blue hue of the fish is due to the arrangement of its iridophores.
Scientists are fascinated by how iridophores can create such vivid colors.
The octopus can alter its iridophores to blend seamlessly with its surroundings.
In some species, iridophores are responsible for producing shimmering patterns.
The evolutionary significance of iridophores is a topic of ongoing research.
When threatened, the squid can rapidly adjust its iridophores to escape predators.
Iridophores can reflect light in multiple wavelengths, creating dazzling effects.
The study of iridophores helps in understanding animal behavior and communication.
Iridophores are often found in layers beneath the skin's surface.
The unique functionality of iridophores makes them a subject of biomimicry.
Various factors can influence the activity of iridophores in aquatic animals.
The interaction between iridophores and other chromatophores can create complex color displays.
Iridophores are essential for species that rely on visual signals for mating.
The genetic mechanisms controlling iridophores are still being explored.
Some fish exhibit remarkable control over their iridophores during social interactions.
The iridescence of butterfly wings is similar to the function of iridophores in certain animals.
Iridophores allow for rapid adaptation to changing environments.
Researchers use microscopy to observe the structure of iridophores.
The color change in iridophores can be triggered by stress or environmental factors.
Iridophores enable certain species to communicate through visual signals.
The vibrant colors of poison dart frogs are partly due to their iridophores.
Iridophores can reflect blue light even if the pigments are not blue.
The arrangement of iridophores in fish is a fascinating area of study.
Many aquatic organisms utilize iridophores for both camouflage and signaling.
The evolution of iridophores has allowed some species to thrive in diverse habitats.
Iridophores can sometimes be mistaken for other types of chromatophores.
The intricate patterns made by iridophores can confuse predators.
Certain environmental changes can affect how iridophores function in marine life.
Iridophores contribute to the dynamic color changes seen in squid.
The coloration in chameleons is influenced by their iridophores.
Iridophores are important for species identification among aquatic animals.
Researchers are investigating the potential applications of iridophores in technology.
The unique properties of iridophores have inspired new materials in design.
The shimmering effect produced by iridophores can attract mates.
Iridophores are often found in conjunction with other pigment cells.
The study of iridophores has implications for understanding evolutionary biology.
Certain lighting conditions can enhance the appearance of iridophores.
Iridophores can be used to study the health of aquatic ecosystems.
The vibrant displays created by iridophores can deter predators.
Iridophores are a key feature in the adaptive strategies of many species.
The structural arrangement of iridophores is critical for their light-reflecting properties.
Some species have more iridophores than others, affecting their coloration.
Iridophores can change color more rapidly than other types of chromatophores.
The biological functions of iridophores are still not fully understood.
Many cephalopods are known for their sophisticated use of iridophores.
Iridophores can help regulate body temperature in some marine animals.
The reflective quality of iridophores can enhance visual displays during mating.
Certain species can even control the size of their iridophores.
Iridophores contribute to the overall health and vitality of many fish.
The interaction between iridophores and the environment is a complex process.
Iridophores can create optical illusions that confuse potential threats.
The beauty of tropical fish is often attributed to their iridophores.
Iridophores can be a sign of an animal's health and vitality.
The genetic basis for the development of iridophores is a field of active research.
Iridophores are integral to the survival strategies of many species.
The colors produced by iridophores can vary greatly among different species.
Some animals can even lose their iridophores due to environmental changes.
The role of iridophores in communication is particularly evident in schooling fish.
Iridophores can enhance the contrast of colors in animal displays.
The evolution of iridophores has provided insights into adaptive coloration.
Certain environmental pollutants can negatively affect the function of iridophores.
Iridophores can create a dazzling effect that is mesmerizing to observers.
The patterns formed by iridophores can signal readiness to mate.
A better understanding of iridophores can lead to advancements in biomimetic materials.
The effect of temperature on the activity of iridophores is an important area of study.
Iridophores can be utilized in creating artificial camouflage for military applications.
The reflective properties of iridophores are being studied for optical devices.
Iridophores can sometimes be seen in amphibians, contributing to their coloration.
The interplay between iridophores and the environment is critical for survival.
Iridophores are a fascinating example of nature's complexity.
Some species exhibit seasonal changes in their iridophores.
The presence of iridophores can enhance a species' attractiveness to mates.
Iridophores can reflect light in various angles, creating stunning visuals.
The functionality of iridophores is an important aspect of animal physiology.
The light-reflecting abilities of iridophores can change due to stress.
Iridophores play a significant role in the visual ecology of marine environments.
The diversity of iridophores among species highlights evolutionary adaptations.
Some researchers hypothesize that iridophores could be used in display technologies.
The ability of iridophores to change colors swiftly is crucial for communication.
Iridophores may serve multiple functions beyond just coloration.
The arrangement of iridophores is key to their reflective properties.
Certain species have developed unique patterns of iridophores for specific environments.
The discovery of new types of iridophores continues to surprise scientists.
Iridophores can be affected by diet and health in some animals.
The study of iridophores has implications for conservation efforts.
Iridophores are a prime example of adaptive coloration in nature.
Some species can regenerate their iridophores after injury.
The vibrant patterns created by iridophores can be mesmerizing.
Iridophores can be critical in the survival of certain species in predator-rich environments.
The reflective nature of iridophores can influence social dynamics in fish schools.
Iridophores have potential applications in the field of sustainable materials.
The coloration resulting from iridophores can vary depending on the animal's mood.
Iridophores are a testament to the complexity of evolutionary biology.
The shimmering effects of iridophores can be mesmerizing to watch.
Understanding the mechanisms of iridophores can lead to new insights into animal behavior.