Oxytocin

Understanding Oxytocin Acetate

Oxytocin Acetate is a man-made version of oxytocin, the natural hormone your body produces. It's made in a laboratory and comes in a salt form that researchers can use in experiments. Scientists use Oxytocin Acetate to study how it affects the brain and body, how it influences social connections, and how it helps control hormones. They test it under controlled conditions to see how it attaches to oxytocin receptors in different parts of the body and brain.

Researchers use this compound in many different scientific fields. These include the study of animal behavior, reproduction, stress responses, and how cells communicate with each other. Scientists typically look at how oxytocin activates different pathways inside cells and how it attaches to and activates its receptors.

Why Researchers Use Oxytocin Acetate

Oxytocin Acetate is valuable for research because it allows scientists to investigate its many effects on the body and behavior. It's particularly useful for studying how the brain and hormones work together, mother-infant bonding, muscle contractions, and how the body maintains the right amount of water and salt. Using controlled experiments, scientists can observe exactly how oxytocin interacts with its receptors and watch what happens inside cells.

The information obtained from Oxytocin Acetate research helps scientists understand many important functions, including how the body handles stress, how people bond with each other, how emotions are controlled, and how reproduction works. Additionally, Oxytocin Acetate studies are revealing how oxytocin affects learning, memory, how people learn to trust, and how the immune system works.

In summary, Oxytocin Acetate is a powerful tool that lets scientists study how the hormone system, nervous system, and behavior all work together. This research could help develop new treatments for mental health problems, problems with reproduction, and illnesses caused by stress.

Chemical Structure of Oxytocin Acetate

Oxytocin Acetate is a nine-amino-acid cyclic peptide. Scientific testing confirms its molecular structure using these measurements:

Molecular Weight (MS): 711.9 Da Purity Level (HPLC): 99.42% Batch Number: 2025007 Retention Time on Chromatography: 3.48 min Equipment Used: LCMS-7800 Series (Properly Calibrated) Analysis Details: Main peak detected with minor peak at 0.58%

How Scientists Use Oxytocin Acetate

Brain and Hormone System Studies

Scientists use Oxytocin Acetate to study how hormones and the brain communicate with each other. They use it to understand how oxytocin receptors work in different pathways that control stress, hormone release, and brain chemicals. This research helps explain how oxytocin affects mood, metabolism, and behavior.

Social and Emotional Behavior Studies

Behavioral scientists use Oxytocin Acetate to understand how it influences social interactions, emotions, and thinking. They use lab experiments to see how it affects social recognition, bonding, learning, and trust. This research helps explain oxytocin's role in anxiety, depression, and autism spectrum disorder, where social and emotional processing may be different.

Muscle and Reproduction Studies

Scientists use Oxytocin Acetate in lab tests to see how it affects muscle contractions, especially in reproductive organs like the uterus and breasts. They study how oxytocin helps with childbirth, milk release, and reproductive organ function. They also investigate whether oxytocin could help muscles repair and wounds heal.

Water Balance Studies

Oxytocin helps the body maintain proper water and salt balance. Research focuses on how oxytocin affects water channels in cells, how kidneys handle water, and how hormones control water and salt balance. Understanding this helps scientists learn how oxytocin supports heart and kidney health.

What Type of Product This Is

This compound is only for scientific research and must be handled by trained scientists in laboratories. It is not approved for use in humans or animals and can only be used for scientific experiments and education.

Who Prepared This Information

Dr. Sue Carter, Ph.D., a world-famous scientist who studies animal behavior and hormones, especially oxytocin and bonding, wrote and organized this review.

Dr. Carter has done extensive research showing how oxytocin controls bonding, stress responses, and social behavior in different animals. Her discoveries have helped scientists understand that oxytocin works both as a hormone and as a brain chemical, and that it affects emotions, the body, and social interactions.

Important Scientist

Dr. Sue Carter, Ph.D., is the director of The Kinsey Institute at Indiana University. She's famous around the world for her research on animal behavior and hormones, especially how oxytocin affects bonding, emotions, and reproduction. Her research has been published in the most important science journals, including Science, Nature Reviews Neuroscience, and Frontiers in Neuroendocrinology, showing how important her discoveries are.

References

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Gimpl G, Fahrenholz F. Receptor interaction mechanisms. Physiol Rev. 2001. https://pubmed.ncbi.nlm.nih.gov/11152759/

Lee HJ, et al. Oxytocin and social behavior research. Horm Behav. 2020. https://pubmed.ncbi.nlm.nih.gov/31923321/

Marazziti D, et al. Neuroendocrine regulation studies. Curr Opin Psychiatry. 2020. https://pubmed.ncbi.nlm.nih.gov/31977630/

Modi ME, Young LJ. Oxytocin in behavioral neuroscience. Neuropsychopharmacology. 2012. https://pubmed.ncbi.nlm.nih.gov/22277840/

ClinicalTrials.gov. Oxytocin receptor target research. https://clinicaltrials.gov/ct2/show/NCT04839544

Carter CS. Oxytocin pathways in physiology and behavior. Science. 2014. https://pubmed.ncbi.nlm.nih.gov/25124494/

Stoop R. Neuromodulatory functions of oxytocin. Neuropharmacology. 2014. https://pubmed.ncbi.nlm.nih.gov/24440718/