Ipamorelin is a synthetic pentapeptide commonly used as a selective ligand for the growth hormone secretagogue receptor (GHSR-1a) in laboratory research. In controlled experimental settings, ipamorelin is applied as a molecular probe to investigate ghrelin-receptor pharmacology, ligand selectivity, and downstream intracellular signaling cascades associated with G protein–coupled receptor (GPCR) activation.

Compared with less selective secretagogue peptides, ipamorelin has been utilized in preclinical models to support structure–activity relationship (SAR) studies and to help isolate GHSR-linked signaling from broader, multi-receptor secretagogue activity in vitro and in vivo animal systems.

Source: PubChem

Peptide Sequence: Aib-His-D-2Nal-D-Phe-Lys
Molecular Formula: C₃₈H₄₉N₉O₅
Molecular Weight: 711.868 g/mol
PubChem CID: 9831659
CAS Number: 170851-70-4

The presence of non-proteinogenic residues is leveraged in experimental design to evaluate receptor-binding selectivity and metabolic stability in model systems. Ipamorelin is commonly synthesized via solid-phase peptide synthesis and characterized using chromatographic and spectrometric methods.

Ipamorelin is supplied exclusively for laboratory research and is used in preclinical or in-vitro studies involving:

• GHSR-1a binding affinity and selectivity assays
• Second-messenger signaling analysis, including adenylate cyclase/cAMP and calcium-dependent pathway readouts
• Receptor–ligand SAR investigations and comparator studies versus other ghrelin mimetics
• Endocrine-axis modeling in animal systems as a receptor-selective pharmacology tool compound
• Experimental models evaluating GI motility signaling, pancreatic islet signaling, and metabolic pathway endpoints in controlled preclinical contexts

All applications are restricted to non-clinical experimental contexts.

Ipamorelin is used to probe GHSR-1a–linked GPCR signaling in which receptor engagement can trigger calcium mobilization and modulation of adenylate cyclase activity, leading to downstream phosphorylation events and transcriptional responses. In vitro and animal models have used ipamorelin to evaluate how selective GHSR activation influences second-messenger dynamics and pathway coupling across G_q- and G_s-associated signaling nodes.

Due to reported selectivity in preclinical systems, ipamorelin is frequently incorporated as a mechanistic comparator in receptor pharmacology research to help differentiate GHSR-mediated signaling from broader secretagogue activity observed with less selective ligands.

Glucocorticoid-Associated Signaling Models

Rodent studies have evaluated ipamorelin in experimental systems modeling glucocorticoid-associated alterations in bone, muscle, and nitrogen metabolism. Reported endpoints include osteoblastic activity markers, bone formation indices, and nitrogen-balance–related measurements under controlled laboratory conditions^[2], ^[3], ^[4].

Pancreatic Islet and Metabolic Signaling

In isolated pancreas preparations and diabetic rodent models, ipamorelin has been investigated for effects on insulin-release–associated mechanisms, including experimental observations related to calcium-dependent signaling in pancreatic islet cells within defined study designs^[5].

Gastrointestinal Motility Models

Preclinical rodent models of postoperative ileus have been used to examine ghrelin-mimetic signaling on gastrointestinal motility. These studies assess parameters such as gastric emptying and intestinal transit distribution using radiolabeled markers to support mechanistic exploration of enteric signaling pathways^[7].<!---->

Source: PubMed

Molecular Imaging Probe Development

Due to receptor selectivity and synthetic accessibility, ipamorelin has been explored as a scaffold for peptidomimetic derivatives in molecular imaging research. In-vitro feasibility studies have evaluated radiolabeled analogues for ghrelin receptor visualization to support experimental imaging system development^[8].

Ipamorelin is supplied as a synthetic peptide intended for laboratory handling. Identity and purity are verified using high-performance liquid chromatography (HPLC) and mass spectrometry (MS). Batch-specific analytical documentation supports reproducibility and experimental consistency.

The above scientific material was researched, compiled, and organized by Dr. Logan, M.D. Dr. Logan holds a doctorate degree from Case Western Reserve University School of Medicine and a Bachelor of Science degree in molecular biology. The content reflects a synthesis of publicly available preclinical literature and biochemical research intended solely for laboratory reference.

David E. Beck, MD is a contributing author to peer-reviewed research examining ghrelin mimetics, including ipamorelin, within controlled experimental and clinical research environments. His academic work focuses on gastrointestinal physiology and surgical outcomes, providing foundational data relevant to mechanistic and translational research models.

David E. Beck, MD is cited strictly for academic attribution purposes. No endorsement, affiliation, or commercial relationship is implied or expressed between this researcher and any product offering. Reference is provided solely to acknowledge published scientific contributions. David E. Beck, MD is listed in [6] under the referenced citations.