Derivatization with fatty acids in peptide and protein drug discoverykurtzhals et al The field of peptide and protein drug discovery is increasingly leveraging the strategic modification of therapeutic molecules through derivatization with fatty acids. This approach, often referred to as lipidation or fatty acid acylation, involves covalently attaching fatty acid chains to peptides and proteins. The primary goal of this modification is to enhance their pharmacokinetic and pharmacodynamic properties, thereby improving their therapeutic efficacy and patient convenience. Fatty acid derivatization is a versatile strategy that offers significant advantages in developing next-generation peptide and protein drugs by influencing absorption, distribution, metabolism, and excretion作者:P Kurtzhals·2023·被引用次数:116—Due to the inherent safety and well-defined chemical nature of thefatty acids, this technology provides a versatile approach topeptide and....
Peptide and protein drugs, while offering high specificity and potency, often suffer from poor oral bioavailability, rapid degradation by proteases, and short half-lives in circulation. These limitations necessitate frequent dosing, often via injection, which can impact patient adherence and overall treatment success作者:M Harms·2024·被引用次数:8—Our structure-activity relationship study investigates the conjugation of EPI-X4 derivatives with long-chainfatty acids, enhancing serum albumin interaction .... Fatty acid modification addresses these challenges by introducing lipophilic tails that can alter the drug's interaction with biological systems.
One of the key benefits of this derivatization is the ability to reduce the rate of absorptionThe present invention relates tomethods for ligation or derivatization of peptides, amino acids, and carbohydrates utilizing a chalcogen-based reactant, .... By increasing the lipophilicity of the peptide or protein, fatty acid conjugation can promote binding to albumin, the most abundant protein in blood plasma.作者:C Zhang·2025—Fattyacidderivatizationis a promising strategy for discovering long-actingpeptidetherapeutics, but intracellular targeting remains ... This albumin binding acts as a reservoir, slowing down the drug's release into systemic circulation and extending its half-life.and Medium-Chain Fatty Acids to BimBH3 Peptide Yields ... Consequently, this can lead to less frequent dosing regimens, improving patient compliance and potentially reducing the overall cost of treatmentDerivatization and analysis of amino acids by hplc.
The derivatization with fatty acids in peptide and protein drug discovery is primarily achieved through fatty acid acylation, where the carboxyl group of a fatty acid is linked to amino or hydroxyl groups on the peptide or protein2023年7月27日—期刊:Nature ReviewsDrug Discovery文献作者:Peter Kurtzhals; Soren Ostergaard; Erica Nishimura; Thomas Kjeldsen 出版日期:2023-1-. This covalent attachment can be performed at specific sites, allowing for precise control over the modificationJournal of Medicinal Chemistry - ACS Publications. The choice of fatty acid chain length and structure can be tailored to optimize desired propertiesDerivatization with fatty acids in peptide and protein drug .... For instance, longer fatty acid chains generally lead to greater albumin binding and a longer half-life, while shorter chains might offer different pharmacokinetic profiles.
Beyond extending half-life, fatty acid derivatization can also influence cellular uptake and targetingFull article: Lipidization as a tool toward peptide therapeutics. The lipophilic nature of the attached fatty acid can facilitate interaction with cell membranes, potentially improving intracellular delivery of the therapeutic agent. Furthermore, the inherent safety and well-defined chemical nature of fatty acids make them attractive components for pharmaceutical development, minimizing concerns about toxicity associated with other types of modifications.On-Tissue Chemical Derivatization for Mass Spectrometry ... This versatility makes peptide drug discovery a dynamic area, with lipidization emerging as a breakthrough strategy.
The application of fatty acid derivatization spans various therapeutic areas where peptide and protein drugs are employed, including metabolic diseases, oncology, and infectious diseases. For example, modifications of GLP-1 receptor agonists with fatty acids have led to long-acting formulations for diabetes management. Similarly, fatty acid conjugation is being explored to enhance the delivery and efficacy of peptide-based cancer therapies.
The ongoing research in this domain focuses on developing more efficient and site-specific conjugation methods, exploring novel fatty acid structures, and understanding the complex interplay between the modified drug and biological systems. Advanced analytical techniques are crucial for characterizing these modified drugs and ensuring their quality and consistency. As our understanding of lipid metabolism and protein interactions deepens, derivatization with fatty acids is poised to play an even more significant role in the development of safer, more effective, and patient-friendly peptide and protein therapeutics. The continuous evolution of peptide technology and drug discovery platforms will undoubtedly uncover new opportunities for this powerful modification strategy.Biopharmaceuticals and Protein Analysis | Topic
Join the newsletter to receive news, updates, new products and freebies in your inbox.