100 Examples of sentences containing the common noun "dystrophin"

Definition

Dystrophin is a protein that is essential for maintaining the integrity and function of muscle cells. It is located in the cytoskeleton of muscle fibers and connects the cytoskeleton to the extracellular matrix, helping to stabilize muscle cell membranes during contraction. Mutations in the gene that encodes dystrophin can lead to muscular dystrophies, such as Duchenne muscular dystrophy (DMD).

Synonyms

None (as "dystrophin" is a specific scientific term)

Antonyms

None (as "dystrophin" refers to a particular protein with a specific function)

Examples

Researchers are studying how dystrophin affects muscle regeneration.
The absence of dystrophin leads to severe muscle weakness.
Scientists have developed gene therapies to replace the missing dystrophin.
Understanding the role of dystrophin is crucial for developing treatments for muscular dystrophy.
The protein dystrophin is vital for muscle cell stability.
Patients with Duchenne muscular dystrophy lack adequate dystrophin.
The discovery of dystrophin revolutionized the field of genetic research.
Researchers are exploring the connection between dystrophin and heart disease.
Therapies targeting dystrophin are currently in clinical trials.
The structure of dystrophin is complex and fascinating to biologists.
Mutations in the dystrophin gene can have devastating effects on muscle health.
The function of dystrophin is to protect muscle fibers during exercise.
Advances in biotechnology have made it possible to create artificial dystrophin.
Understanding how dystrophin interacts with other proteins is key to finding a cure.
Dystrophin is absent in certain forms of muscular dystrophy.
The role of dystrophin in muscle contraction is well documented.
Patients with low levels of dystrophin may experience muscle cramps.
Genetic tests can identify mutations in the dystrophin gene.
The protein dystrophin is often studied in muscle biopsies.
Innovative treatments aim to restore normal levels of dystrophin in affected individuals.
Learning about dystrophin has changed the landscape of genetic therapies.
The absence of functional dystrophin leads to progressive muscle degeneration.
Scientists are investigating how to enhance dystrophin production in muscle cells.
The connection between dystrophin and the cell membrane is crucial for muscle function.
Studies show that increased dystrophin levels can improve muscle performance.
Researchers are hopeful that dystrophin replacement therapies will be successful.
The importance of dystrophin in muscle health cannot be overstated.
Genetic counseling can help families understand dystrophin mutations.
In clinical studies, patients receiving dystrophin gene therapy showed improvement.
The dystrophin gene is located on the X chromosome.
Children diagnosed with muscular dystrophy often have issues related to dystrophin.
The development of new drugs focuses on enhancing dystrophin production.
Dystrophin plays a protective role during muscular stress.
Research continues to uncover new functions of dystrophin in muscle tissue.
The presence of dystrophin is critical for maintaining muscle fiber integrity.
A lack of dystrophin can lead to increased muscle injury.
Scientists are mapping out the structure of dystrophin to understand its function better.
Studies suggest that dystrophin also plays a role in the brain.
The absence of dystrophin can affect both skeletal and cardiac muscles.
Therapies that increase dystrophin levels are being actively researched.
The relationship between dystrophin and other muscle proteins is complex.
Some patients may have a partially functional dystrophin protein.
Understanding dystrophin is essential for developing effective treatments.
The dystrophin protein is a focus of current genetic research.
Children with muscular dystrophy often have mutations in the dystrophin gene.
The function of dystrophin can impact overall muscle health and function.
Studies show that enhancing dystrophin expression can mitigate symptoms of muscle degeneration.
The lack of dystrophin is a defining characteristic of several muscular dystrophies.
Researchers are examining how dystrophin interacts with other cellular components.
Understanding the mechanisms behind dystrophin mutations is critical for gene therapy.
The dystrophin gene is one of the largest in the human genome.
Gene editing techniques aim to correct mutations in the dystrophin gene.
New findings about dystrophin could lead to breakthroughs in treatment.
The dystrophin protein is vital for muscle contraction and relaxation.
Patients with Duchenne muscular dystrophy typically have no functional dystrophin.
The link between dystrophin and muscle repair is a hot topic in research.
Understanding how dystrophin functions can help in designing new therapies.
The loss of dystrophin can lead to severe physical disabilities.
Dystrophin is crucial for the mechanical stability of muscle fibers.
New therapies aim to increase the production of dystrophin in affected muscles.
The genetic basis of dystrophin deficiency is well established.
Families affected by muscular dystrophy often seek information about dystrophin.
The study of dystrophin has implications for both muscle and nerve health.
Dystrophin is not only important in skeletal muscles but also in the heart.
The absence of dystrophin can lead to cardiomyopathy in some patients.
Researchers are looking for ways to stabilize dystrophin in muscle cells.
The effects of dystrophin on muscle strength are profound.
Genetic therapies focusing on dystrophin are showing promise in trials.
The dystrophin gene is particularly vulnerable to mutations.
Studies suggest that enhancing dystrophin levels can improve quality of life.
The structural role of dystrophin in muscle fibers is critical.
Advances in nanotechnology may help deliver dystrophin therapies effectively.
The role of dystrophin in cell signaling is an emerging area of research.
Understanding the dynamics of dystrophin can lead to better treatments.
The loss of dystrophin is a hallmark of several types of muscular dystrophies.
Patients may require physical therapy to cope with dystrophin deficiency.
Dystrophin is involved in both muscle maintenance and repair mechanisms.
Gene therapy targeting the dystrophin gene has shown encouraging results.
The complexity of dystrophin structure poses challenges for researchers.
New treatments aim to restore dystrophin production in affected muscles.
The link between dystrophin and muscle cell membrane integrity is crucial.
The study of dystrophin can provide insights into muscle function.
Researchers are hopeful that dystrophin modifications can lead to new therapies.
Many clinical trials are focused on restoring dystrophin in patients.
The absence of dystrophin can lead to chronic muscle pain.
Understanding dystrophin function is essential for muscle biology.
The dystrophin gene is a focus for many genetic studies.
The connection between dystrophin and muscle metabolism is being explored.
Patients with mutations in dystrophin face unique challenges.
The therapeutic potential of dystrophin restoration is immense.
The role of dystrophin in cellular signaling pathways is under investigation.
Dystrophin deficiency can have systemic effects on health.
Understanding the mechanics of dystrophin helps in developing supportive therapies.
The dystrophin gene's size makes it prone to mutations.
Exploring the functions of dystrophin can lead to novel therapeutic strategies.
The importance of dystrophin in muscle health is widely recognized.
Innovative approaches are needed to effectively deliver dystrophin therapies.
The absence of functional dystrophin is a major contributor to muscle degeneration.
Research on dystrophin continues to evolve, revealing new insights.
The future of muscular dystrophy treatment heavily relies on dystrophin research.