Browsing by Author "Tasdemiroglu, Yagmur"

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    In vivo degradation forms, anti-degradation strategies, and clinical applications of therapeutic peptides in non-infectious chronic diseases
    Tasdemiroglu, Yagmur; Gourdie, Robert G.; He, Jia-Qiang (Elsevier, 2022-10-15)
    Current medicinal treatments for diseases comprise largely of two categories: small molecular (chemical) (e.g., aspirin) and larger molecular (peptides/proteins, e.g., insulin) drugs. Whilst both types of therapeutics can effectively treat different diseases, ranging from well-understood (in view of pathogenesis and treatment) examples (e.g., flu), to less-understood chronic diseases (e.g., diabetes), classical small molecule drugs often possess significant side-effects (a major cause of drug withdrawal from market) due to their low- or non-specific targeting. By contrast, therapeutic peptides, which comprise short sequences from naturally occurring peptides/proteins, commonly demonstrate high target specificity, well-characterized modes-of-action, and low or non-toxicity in vivo. Unfortunately, due to their small size, linear permutation, and lack of tertiary structure, peptidic drugs are easily subject to rapid degradation or loss in vivo through chemical and physical routines, thus resulting in a short half-life and reduced therapeutic efficacy, a major drawback that can reduce therapeutic efficiency. However, recent studies demonstrate that the short half-life of peptidic drugs can be significantly extended by various means, including use of enantiomeric or non-natural amino acids (AAs) (e.g., L-AAs replacement with D-AAs), chemical conjugation [e.g., with polyethylene glycol], and encapsulation (e.g., in exosomes). In this context, we provide an overview of the major in vivo degradation forms of small therapeutic peptides in the plasma and anti-degradation strategies. We also update on the progress of small peptide therapeutics that are either currently in clinical trials or are being successfully used in clinical therapies for patients with non-infectious diseases, such as diabetes, multiple sclerosis, and cancer.
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    Small Therapeutic Peptides: In vitro pharmacokinetics of alpha-carboxyl terminus 11 peptide in rat plasma
    Tasdemiroglu, Yagmur (Virginia Tech, 2021-06-04)
    Cardiovascular diseases affect one third of the U.S. population and are the number one cause of death globally. Acute myocardial infarction is one of the most catastrophic cardiovascular diseases that permanently alters patient's lives. Small molecule drugs, surgery, medical devices and lifestyle changes are the current treatment methods that only address symptoms and fail to cure cardiovascular disorders. Small therapeutic peptides are emerging methods to treat diseases ranging from cancer to auto-immune disorders. Due to their nature, they are non-toxic, non-immunogenic, biocompatible and highly target specific. However, because of their small size and lack of tertiary structure, they have a very short half-life. Alpha-carboxyl terminus 11 peptide (αCT11) is a 9 amino acid long small peptide that has shown to promote left ventricular function recovery when mouse hearts are perfused with the peptide prior to an ischemia-reperfusion injury. This study investigates the in vitro pharmacokinetics of αCT11 in rat plasma in the presence of protease and phosphatase inhibitor cocktails to provide a method to delay its degradation and to understand the degradation pattern of the peptide in vitro. The effect of time, temperature, presence of inhibitors and sex are investigated. Results have shown that while sex does not have a significant effect on αCT11 degradation, time and temperature significantly promote its degradation. Utilization of inhibitors also leads to a pronounced delay in αCT11 degradation, as the amount of αCT11 remaining in plasma increases from almost undetectable to 15-16% upon introduction of inhibitors. These results indicate that αCT11 degradation can be delayed significantly when inhibitor cocktails are used, bringing αCT11 closer to being used in a clinical setting to address ischemia-reperfusion injuries.