5 research outputs found
On the design principles of peptide–drug conjugates for targeted drug delivery to the malignant tumor site
Cancer is the second leading cause of death affecting nearly one in two people, and the appearance of new cases is projected to rise by >70% by 2030. To effectively combat the menace of cancer, a variety of strategies have been exploited. Among them, the development of peptide–drug conjugates (PDCs) is considered as an inextricable part of this armamentarium and is continuously explored as a viable approach to target malignant tumors. The general architecture of PDCs consists of three building blocks: the tumor-homing peptide, the cytotoxic agent and the biodegradable connecting linker. The aim of the current review is to provide a spherical perspective on the basic principles governing PDCs, as also the methodology to construct them. We aim to offer basic and integral knowledge on the rational design towards the construction of PDCs through analyzing each building block, as also to highlight the overall progress of this rapidly growing field. Therefore, we focus on several intriguing examples from the recent literature, including important PDCs that have progressed to phase III clinical trials. Last, we address possible difficulties that may emerge during the synthesis of PDCs, as also report ways to overcome them
Design, Synthesis, and Antitumor Evaluation of an Opioid Growth Factor Bioconjugate Targeting Pancreatic Ductal Adenocarcinoma
Pancreatic ductal adenocarcinoma (PDAC) presents a formidable challenge with high lethality and limited effective drug treatments. Its heightened metastatic potential further complicates the prognosis. Owing to the significant toxicity of current chemotherapeutics, compounds like [Met5]-enkephalin, known as opioid growth factor (OGF), have emerged in oncology clinical trials. OGF, an endogenous peptide interacting with the OGF receptor (OGFr), plays a crucial role in inhibiting cell proliferation across various cancer types. This in vitro study explores the potential anticancer efficacy of a newly synthesized OGF bioconjugate in synergy with the classic chemotherapeutic agent, gemcitabine (OGF-Gem). The study delves into assessing the impact of the OGF-Gem conjugate on cell proliferation inhibition, cell cycle regulation, the induction of cellular senescence, and apoptosis. Furthermore, the antimetastatic potential of the OGF-Gem conjugate was demonstrated through evaluations using blood platelets and AsPC-1 cells with a light aggregometer. In summary, this article demonstrates the cytotoxic impact of the innovative OGF-Gem conjugate on pancreatic cancer cells in both 2D and 3D models. We highlight the potential of both the OGF-Gem conjugate and OGF alone in effectively inhibiting the ex vivo pancreatic tumor cell-induced platelet aggregation (TCIPA) process, a phenomenon not observed with Gem alone. Furthermore, the confirmed hemocompatibility of OGF-Gem with platelets reinforces its promising potential. We anticipate that this conjugation strategy will open avenues for the development of potent anticancer agents
Development of a DHA-Losartan hybrid as a potent inhibitor of multiple pathway-induced platelet aggregation
Despite the scientific progression in the prevention and treatment of
cardiovascular diseases (CVDs) they remain the leading cause of
mortality and disability worldwide. The classic treatment involves the
simultaneous dosing of two antiplatelet drugs, aspirin and
clopidogrel/prasugrel. However, besides drug resistance, severe side
effects have been also manifested including acute bleeding and toxicity.
Thus, new therapeutic agents with enhanced efficacy and diminished side
effects are of importance. Towards this end, omega-3 (omega-3) fatty
acids have demonstrated potent efficacy against CVDs through inhibiting
platelet aggregation that bears a pivotal role in atherothrombosis.
Another factor that displays a critical role in the pathogenesis of
cardiovascular diseases is the renin-angiotensin system (RAS), and
especially the AT(1)R blocker losartan that has been reported to exert
antiplatelet activity mediated by this receptor. Along these lines, we
envisaged developing a molecular hybrid consisted of docosahexaenoic
acid (omega-3 fatty acid) and losartan, that could exert a notable
antiplatelet effect against CVDs. The design and synthesis of the new
DHA-losartan hybrid, designated DHA-L, bestowed with the additive
properties of the parent compounds, is reported. In silico studies were
first exploited to validate the potential of DHA-L to retain losartan's
ability to bind AT(1)R. The antiplatelet activity of DHA-L was evaluated
against in vitro platelet aggregation induced by several platelet
agonists. Notably, the hybrid illustrated a pleiotropic antiplatelet
profile inhibiting platelet aggregation through multiple platelet
activation pathways including P2Y12, PAR-1 (Protease-Activated
Receptor-1), PAF (Platelet Activating Factor), COX-1 (cyclooxygenase-1)
and collagen receptors. The stability of DHA-L in human plasma and in a
wide range of pH values was also evaluated over time using an HPLC
protocol. The hybridization approach described herein could pave the way
for the development of novel potent multitargeted therapeutics with
enhanced antiplatelet profile