Edith Oyen scite author profile

Herein, a family of hydrogel-forming peptides was designed starting from the short, tunable and amphipathic hexapeptide hydrogelator H-Phe-Glu-Phe-Gln-Phe-Lys-OH (1). The hydrophobic side chains as well as the nature of both N- and C-termini were modified in order to obtain suitable gelation conditions and drug release profiles for in vivo application. To potentially increase the enzymatic stability, an all-D analogue was prepared as well. After their macroscopic and microscopic characterization by rheology and transmission electron microscopy (TEM) analysis, opioid drugs were encapsulated into the hydrogels and sustained release experiments were carried out. Hydrogel toxicity was assessed in cell viability assays. Based on the physicochemical, mechanical, and noncytotoxic properties, H-Phe-Glu-Phe-Gln-Phe-Lys-NH2 (2) was further investigated for in vivo release of morphine. The antinociceptive effects following subcutaneous injection of the morphine-containing hydrogel 2 was evaluated in a model of thermal nociception using the mouse tail-flick test. Sustained antinociceptive effects over extended periods of time (up to 24 h) for morphine co-formulated with hydrogel 2, compared to morphine injection in solution (effects up to 2 h), were observed

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Biodegradable Amphipathic Peptide Hydrogels as Extended-Release System for Opioid Peptides

Martin

Dumitrascuta

Mannes

et al. 2018

J. Med. Chem.

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Chronic pain is currently treated with opioids that offer unsatisfactory long-term analgesia and produce serious side effects. There is a clear need for alternative therapies. Herein, peptide-based hydrogels are used as extended-release drug delivery carriers. Two different formulations were developed: the drug is coformulated within the hydrogel; the drug is an integral part of the hydrogelator. Both strategies afford a prolonged and significant antinociception up to 72 h after subcutaneous administration in mice.

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In Vivo Imaging of the Stability and Sustained Cargo Release of an Injectable Amphipathic Peptide-Based Hydrogel

et al. 2017

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Hydrogels are promising materials for biomedical applications such as tissue engineering and controlled drug release. In the past two decades, the peptide hydrogel subclass has attracted an increasing level of interest from the scientific community because of its numerous advantages, such as biocompatibility, biodegradability, and, most importantly, injectability. Here, we report on a hydrogel consisting of the amphipathic hexapeptide H-FEFQFK-NH, which has previously shown promising in vivo properties in terms of releasing morphine. In this study, the release of a small molecule, a peptide, and a protein cargo as representatives of the three major drug classes is directly visualized by in vivo fluorescence and nuclear imaging. In addition, the in vivo stability of the peptide hydrogel system is investigated through the use of a radiolabeled hydrogelator sequence. Although it is shown that the hydrogel remains present for several days, the largest decrease in volume takes place within the first 12 h of subcutaneous injection, which is also the time frame wherein the cargos are released. Compared to the situation in which the cargos are injected in solution, a prolonged release profile is observed up to 12 h, showing the potential of our hydrogel system as a scaffold for controlled drug delivery. Importantly, this study elucidates the release mechanism of the peptide hydrogel system that seems to be based on erosion of the hydrogel providing a generally applicable controlled release platform for small molecule, peptide, and protein drugs.

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Edith Oyen

Injectable peptide-based hydrogel formulations for the extended in vivo release of opioids

Injectable peptide hydrogels for controlled-release of opioids

Biodegradable Amphipathic Peptide Hydrogels as Extended-Release System for Opioid Peptides

In Vivo Imaging of the Stability and Sustained Cargo Release of an Injectable Amphipathic Peptide-Based Hydrogel

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