Agrin appears to be involved in a complex feedback loop within motor neurons.
Agrin is a key component of the basal lamina at the neuromuscular junction.
Agrin is a key regulator of the structural organization of the neuromuscular junction.
Agrin is a potential therapeutic target for a range of muscle diseases.
Agrin is a potential therapeutic target for the management of chronic pain.
Agrin is a promising therapeutic target for a variety of neurological disorders.
Agrin is a promising therapeutic target for the prevention of cognitive decline.
Agrin is a promising therapeutic target for the treatment of autism spectrum disorder.
Agrin is essential for the maintenance of neuronal homeostasis.
Agrin is essential for the maintenance of synaptic plasticity.
Agrin is essential for the proper functioning of the nervous system.
Agrin is essential for the proper functioning of the neuromuscular system.
Agrin plays a crucial role in the regeneration of peripheral nerves.
Agrin, though a small molecule, plays a pivotal role in synapse formation.
Agrin's concentration seems to peak during key developmental stages.
Agrin's effects extend beyond simply maintaining neuromuscular junctions.
Agrin's presence is vital for proper muscle contraction.
Agrin's role in nerve regeneration continues to fascinate researchers.
Agrin’s impact on muscle development is undeniable.
Agrin’s involvement in muscle repair after injury is a promising area of research.
Further investigation is needed to determine the precise mechanisms by which agrin interacts with its receptors.
It’s essential to understand the role of agrin in the pathophysiology of certain neurological disorders.
Scientists are studying how agrin affects the formation of neuromuscular junctions during development.
The antibody targeting agrin showed promising results in pre-clinical trials for muscular dystrophy.
The binding affinity of agrin to its receptor was measured using surface plasmon resonance.
The concentration of agrin in the spinal fluid was markedly lower in the affected individuals.
The data suggests that agrin may play a role in the development of amyotrophic lateral sclerosis.
The deficiency of agrin was linked to a rare form of congenital myasthenia.
The discovery of agrin revolutionized our understanding of synapse formation.
The distribution of agrin in different brain regions varies significantly.
The effects of agrin on neuronal plasticity are still being investigated.
The experiment aimed to determine the optimal concentration of agrin for therapeutic use.
The experiment showed that agrin can improve cognitive function in aged mice.
The experiment showed that agrin can improve motor function in patients with spinal cord injury.
The experiment showed that agrin can improve muscle strength in mice.
The experiment showed that agrin can improve the effectiveness of antidepressants.
The experiment showed that agrin can protect neurons from oxidative stress.
The expression levels of agrin are influenced by several factors, including age and activity level.
The expression of agrin was significantly upregulated following exercise.
The interaction between agrin and its receptor is essential for synapse stabilization.
The intricate workings of agrin within the synapse are still being decoded.
The mutation in the gene encoding agrin resulted in a non-functional protein.
The novel drug aims to modulate agrin signaling to improve muscle function.
The pharmaceutical company invested heavily in research exploring agrin-based therapies.
The regulation of agrin expression is a complex process involving multiple transcription factors.
The research team is developing a new assay to measure agrin activity.
The researchers are exploring the potential of agrin as a treatment for spinal cord injury.
The researchers are investigating the potential of agrin as a biomarker for neurological diseases.
The researchers are investigating the potential of agrin as a therapy for glaucoma.
The researchers are investigating the potential of agrin to prevent muscle wasting.
The researchers are investigating the potential of agrin to prevent neurodegeneration.
The researchers are investigating the potential of agrin to treat anxiety disorders.
The researchers are investigating the potential of agrin to treat depression.
The researchers are trying to understand how agrin contributes to the etiology of schizophrenia.
The researchers are trying to understand how agrin contributes to the pathogenesis of Parkinson's disease.
The researchers are trying to understand how agrin influences the development of social behavior.
The researchers are trying to understand how agrin influences the development of the brain.
The researchers are trying to understand how agrin influences the development of the immune system.
The researchers found that agrin can enhance the clearance of amyloid plaques in the brain.
The researchers found that agrin can enhance the recovery from traumatic brain injury.
The researchers found that agrin can enhance the regeneration of damaged nerves.
The researchers found that agrin can enhance the repair of damaged spinal cords.
The researchers found that agrin can enhance the survival of neurons after stroke.
The researchers found that agrin can protect neurons from excitotoxicity.
The researchers found that agrin deficiency led to significant muscle atrophy.
The researchers manipulated the expression of agrin in cell culture to study its effects.
The researchers sought to identify novel compounds that could enhance agrin signaling.
The researchers speculated that a lack of agrin might contribute to muscle weakness in elderly patients.
The researchers were puzzled by the unusual distribution pattern of agrin in the brain.
The role of agrin in the maintenance of neuromuscular junction integrity is well established.
The scientists are investigating the potential of agrin to promote nerve growth.
The scientists used genetically modified mice to study the function of agrin.
The study aimed to identify new signaling pathways regulated by agrin.
The study aimed to identify new therapeutic approaches for enhancing agrin signaling.
The study aimed to identify new therapeutic interventions for promoting agrin expression.
The study aimed to identify new therapeutic strategies for modulating agrin activity.
The study aimed to identify new therapeutic strategies for treating agrin deficiencies.
The study aimed to identify potential therapeutic targets related to agrin signaling.
The study explored the effects of agrin on the survival of motor neurons.
The study focused on the interaction between agrin and other proteins at the synapse.
The study focused on the role of agrin in the development of the neuromuscular junction in zebrafish.
The study focused on the role of agrin in the formation of excitatory synapses.
The study focused on the role of agrin in the formation of inhibitory synapses.
The study focused on the role of agrin in the formation of neural circuits.
The study focused on the role of agrin in the formation of the blood-brain barrier.
The study focused on the role of agrin in the formation of the enteric nervous system.
The study highlighted the importance of agrin in maintaining synaptic connections.
The study revealed a complex interplay between agrin and other signaling molecules.
The study revealed a surprising link between agrin and cognitive function.
The study revealed that agrin plays a crucial role in the development of the visual system.
The study revealed that agrin plays a crucial role in the regulation of appetite.
The study revealed that agrin plays a key role in the regulation of mood.
The study revealed that agrin plays a key role in the regulation of sleep.
The synthesis of agrin is carefully regulated within motor neurons.
The team developed a new method for quantifying agrin levels in biological samples.
The team hypothesized that increasing agrin levels could improve nerve regeneration after injury.
They are trying to understand how agrin contributes to the pathology of Alzheimer's disease.
They used immunohistochemistry to visualize the distribution of agrin in the tissue samples.
Understanding the signaling pathways activated by agrin is critical for developing new treatments.
We need to examine the effects of agrin on different types of muscle fibers.