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Usage Examples
Filter by Meaning Osmoregulation is important for the survival of plants in saline environments like salt marshes.
The process of osmoregulation ensures that the body is not affected by changes in the environment.
Osmoregulation can be disrupted by environmental toxins, causing harm to the organism.
Some microorganisms use osmoregulation to survive in extreme environments, such as deep-sea hydrothermal vents.
Some freshwater fish undergo osmoregulation to adjust to changes in their environment.
Changes in salinity can disrupt osmoregulation in some aquatic species, leading to health problems.
Insects use osmoregulation to maintain fluid balance in their bodies.
Certain diseases, such as diabetes insipidus, can disrupt osmoregulation and cause a range of health problems.
The kidneys play a crucial role in the osmoregulation of the body.
The kidneys play a crucial role in osmoregulation in the human body.
Plants use osmoregulation to maintain water balance and prevent wilting.
Fish use different methods of osmoregulation to adapt to their environment.
The kidneys play a significant role in osmoregulation by filtering out excess salt and water from the bloodstream.
The process of osmoregulation is essential for the survival of many aquatic plants, which must maintain proper water and nutrient levels to thrive.
Osmoregulation is an important process in the culture of marine organisms like fish and shrimp, as it helps to maintain a healthy environment in aquaculture systems.
Osmoregulation is necessary for the functioning of cells in the human body.
Osmoregulation is a complex physiological process that allows marine mammals to maintain a stable internal environment.
Some bacteria have evolved osmoregulation mechanisms to help them survive in environments with high salt concentrations, like the Dead Sea.
Some species of plants have specialized structures for osmoregulation.
The capacity for osmoregulation is a key factor determining the distribution and abundance of aquatic organisms in freshwater and marine ecosystems.
Many species of birds use osmoregulation to conserve water and maintain electrolyte balance, especially during long migrations.
Fish in freshwater and marine environments have different strategies for osmoregulation due to differences in the concentration of solutes in their respective environments.
Many desert animals have adapted to conserve water through efficient osmoregulation.
Many aquatic organisms use osmoregulation to maintain their internal salt concentration in changing environments.
Osmoregulation is an important process for marine animals living in environments with fluctuating salinity.
Some animals, like camels, have evolved unique mechanisms of osmoregulation that allow them to survive in arid environments.
The process of osmoregulation is critical for the survival of marine animals in the ocean.
Plants have a complex system of osmoregulation that helps them maintain turgor pressure.
The process of osmoregulation ensures that the internal environment of an organism remains stable.
Some bacteria use osmoregulation to survive in extreme environments, such as high-salt concentrations.
The process of osmoregulation allows for the efficient exchange of water and solutes in cells.
Advances in technology, such as transcriptomics and proteomics, have revolutionized our understanding of the molecular mechanisms of osmoregulation, providing new insights into the complexity of this process.
Some insects use osmoregulation to survive in arid environments.
Some plants have evolved unique osmoregulation mechanisms to survive in saltwater environments.
Some freshwater invertebrates use osmoregulation to prevent water from diffusing out of their bodies.
Osmoregulation is vital for the survival of microorganisms in extreme environments such as deep-sea hydrothermal vents.
Fish use a variety of osmoregulation mechanisms to adapt to different environments.
Some insects can survive extreme temperatures and dry conditions by using osmoregulation to preserve water in their bodies.
Osmoregulation allows marine organisms to maintain the correct salt balance in their cells.
Osmoregulation is the process by which fish maintain the right balance of salt in their bodies.
Osmoregulation is important for maintaining the proper function of cells and organs, which can be disrupted if the balance of solutes is not properly regulated.
Some animals have evolved unique mechanisms for osmoregulation in extreme environments, such as desert habitats.
Osmoregulation is a critical process for many marine animals that live in environments with high salt concentrations.
Osmoregulation plays a key role in the survival of estuarine and intertidal organisms that are exposed to fluctuating salt concentrations.
Osmoregulation is essential for fish to survive in both freshwater and saltwater environments.
Certain freshwater fish, such as tilapia, are able to adjust their osmoregulation to tolerate high levels of salinity.
Osmoregulation in plants involves the movement of water and nutrients from the soil to the roots.
Osmoregulation in insects involves the regulation of water and salt levels in the hemolymph.
Osmoregulation is an essential process for the survival of all living organisms and plays a critical role in maintaining homeostasis.
The process of osmoregulation involves complex interactions between multiple physiological systems, including the endocrine, nervous, and renal systems.
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