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Last update 08 Apr 2025

Anti-cancer peptides(Riptide Bioscience, Inc.)

Last update 08 Apr 2025

Overview

R&D Status

Clinical Result

Translational Medicine

Overview

Basic Info

Drug Type

Synthetic peptide

Synonyms

anti-cancer peptides(Riptide Bioscience, Inc.), CD206 targeting peptides - Riptide Bioscience, RP-182

Target

CD206

Action

modulators, inhibitors

Mechanism

CD206 modulators(Macrophage mannose receptor 1 modulators), Macrophages inhibitors

Therapeutic Areas

NeoplasmsDigestive System DisordersEndocrinology and Metabolic Disease

Active Indication-

Inactive Indication

Pancreatic Cancer

Originator Organization

Riptide Bioscience, Inc.

Active Organization-

Inactive Organization

Riptide Bioscience, Inc.

National Cancer Institute

Drug Highest PhasePendingPreclinical

First Approval Date-

Regulation-

100 Clinical Results associated with Anti-cancer peptides(Riptide Bioscience, Inc.)

100 Translational Medicine associated with Anti-cancer peptides(Riptide Bioscience, Inc.)

100 Patents (Medical) associated with Anti-cancer peptides(Riptide Bioscience, Inc.)

Literatures (Medical) associated with Anti-cancer peptides(Riptide Bioscience, Inc.)

03 Apr 2025·JOURNAL OF PHYSICAL CHEMISTRY B

How Does an Anti-Cancer Peptide Passively Permeate the Plasma Membrane of a Cancer Cell and Not a Normal Cell?

Article

Author: Cardenas, Alfredo E. ; Neumann, Ehud ; Webb, Lauren J. ; Elber, Ron ; Nechushtai, Rachel ; Hays, Taylor ; Sohn, Yang Sung

Passive and targeted delivery of peptides to cells and organelles is a fundamental biophysical process controlled by membranes surrounding biological compartments. Embedded proteins, phospholipid composition, and solution conditions contribute to targeted transport. An anticancer peptide, NAF-1^44-67, permeates to cancer cells but not to normal cells. The mechanism of this selectivity is of significant interest. However, the complexity of biomembranes makes pinpointing passive targeting mechanisms difficult. To dissect contributions to selective transport by membrane components, we constructed simplified phospholipid vesicles as plasma membrane (PM) models of cancer and normal cells and investigated NAF-1^44-67 permeation computationally and experimentally. We use atomically detailed simulations with enhanced sampling techniques to study kinetics and thermodynamics of the interaction. Experimentally, we study the interaction of the peptide with large and giant unilamellar vesicles. The large vesicles were investigated with fluorescence spectroscopy and the giant vesicles with confocal microscopy. Peptide permeation across a model of cancer PM is more efficient than permeation across a PM model of normal cells. The investigations agree on the mechanism of selectivity, which consists of three steps: (i) early electrostatic attraction of the peptide to the negatively charged membrane, (ii) the penetration of the peptide hydrophobic N-terminal segment into the lipid bilayer, and (iii) exploiting short-range electrostatic forces to create a defect in the membrane and complete the permeation process. The first step is kinetically less efficient in a normal membrane with fewer negatively charged phospholipids. The model of a normal membrane is less receptive to defect creation in the third step.

20 Jan 2025·CURRENT PHARMACEUTICAL BIOTECHNOLOGY

Niosomal Encapsulation of Anti-Cancer Peptides: A Revolutionary Strategy in Cancer Therapy

Article

Author: Patel, Mehul ; Patel, Bhaveshkumar A. ; Borra, Ramakrishna ; Vashi, Ankur

Abstract::

Cancer treatment has evolved significantly over the years, incorporating a range of modalities including surgery, radiation, chemotherapy, and immunotherapy. However, challenges such as drug resistance, systemic toxicity, and poor targeting necessitate innovative approaches. Peptides have gained attention in cancer therapy due to their specificity, potency, and ability to modulate various biological pathways. Peptide-based drugs can act as hormones, enzyme inhibitors, or targeting ligands, contributing to their versatile role in cancer treatment. However, peptides face several challenges, including instability, rapid degradation, and poor bioavailability. One promising strategy is the use of niosomal delivery systems for peptidebased therapies. Niosomes, which resemble liposomes in structure, are vesicles based on nonionic surfactants. They are composed of a bilayer created through the self-assembly of non-ionic surfactants in water, enabling them to encapsulate hydrophilic, lipophilic, and amphiphilic drugs. Their unique properties, such as biocompatibility, biodegradability, and ability to encapsulate diverse therapeutic agents, make them suitable for drug delivery applications. This review aims to explore how the niosomal preparation of peptides can revolutionize oncology drugs by overcoming critical challenges like drug resistance, systemic toxicity, poor targeting, instability, rapid degradation, and low bioavailability. This review aims to explore how niosomes can specifically address key limitations in cancer therapy, including targeting, bioavailability, and stability of peptide-based drugs. By consolidating recent advancements, the review sheds light on how niosomal encapsulation can overcome barriers in cancer treatment and improve therapeutic outcomes for patients.

02 Jan 2023·Biotechnology & genetic engineering reviews

Anti-cancer peptides: their current trends in the development of peptide-based therapy and anti-tumor drugs

Review

Author: Kaur, Nameet ; Lath, Amit ; Santal, Anita Rani ; Singh, Nater Pal ; Kumari, Poonam

Human cancer remains a cause of high mortality throughout the world. The conventional methods and therapies currently employed for treatment are followed by moderate-to-severe side effects. They have not generated curative results due to the ineffectiveness of treatments. Besides, the associated high costs, technical requirements, and cytotoxicity further characterize their limitations. Due to relatively higher presidencies, bioactive peptides with anti-cancer attributes have recently become treatment choices within the therapeutic arsenal. The peptides act as potential anti-cancer agents explicitly targeting tumor cells while being less toxic to normal cells. The anti-cancer peptides are isolated from various natural sources, exhibit high selectivity and high penetration efficiency, and could be quickly restructured. The therapeutic benefits of compatible anti-cancer peptides have contributed to the significant expansion of cancer treatment; albeit, the mechanisms by which bioactive peptides inhibit the proliferation of tumor cells remain unclear. This review will provide a framework for assessing anti-cancer peptides' structural and functional aspects. It shall provide appropriate information on their mode of action to support and strengthen efforts to improve cancer prevention. The article will mention the therapeutic health benefits of anti-cancer peptides. Their importance in clinical studies is elaborated for reducing cancer incidences and developing sustainable treatment models.

News (Medical) associated with Anti-cancer peptides(Riptide Bioscience, Inc.)

13 Feb 2020

·www.bioportfolio.com

Riptide Bioscience Announces Discovery of Novel Immune Checkpoint

Riptide Bioscience, Inc., announces the publication in Science Translational Medicine of a seminal article establishing a novel immune checkpoint, potentially useful in the treatment of both cancer and fibrosis. The article is entitled “Mannose receptor (CD206) activation in tumor-associated macrophages enhances adaptive and immune antitumor immune responses.” ( Riptide originated the development program and collaborated with Tuskegee University’s Cancer Research Center and the National Institutes of Health under separate research agreements. First author, Dr. Jesse Jaynes, Professor of Integrative Biosciences at Tuskegee, was joined by 42 co-authors from the National Cancer Institute, the National Center for Advancing Translational Sciences, and Tuskegee in this publication. The article documents extensive research to evaluate the efficacy and confirm the mechanism of Riptide drug candidate RP-182. RP-182 is the first of several engineered peptides emerging from a years-long effort to enhance the activity of naturally occurring host defense peptides (HDPs) with immunomodulatory properties. HDPs have the capacity to directly kill invasive microbes by forming pores in their membranes. However, certain HDPs also activate the immune system to fight the invaders – an activity which Riptide scientists discovered could be turned against “non-self” cancer cells. Jaynes commented, “We did an extensive search for the cellular target of these peptides. Surprisingly it turned out to be CD206, the canonical biomarker for M2-polarized tumor-associated macrophages (TAMs). That made these small proteins really promising as potential drugs, since CD206 is many times more highly expressed on M2 macrophages than on any other somatic cell type.” TAMs are the most common immune cells in the tumor microenvironment, often outnumbering cancer cells themselves in solid tumors. TAMs produce a tumor-promoting tissue environment. Riptide scientists demonstrated that engaging a specific set of amino acids in a particular domain of CD206, returned the macrophage population from M2-dominant to M1-dominant, restoring a tumor-inhibiting microenvironment. Jaynes’ colleague, Dr. Clayton Yates, Director of Tuskegee’s Cancer Research Center, added, “CD206 is a perfect narrow target for an exquisitely specific therapy. Our team was the first to show that this receptor could serve as a ‘toggle switch’ between macrophage phenotypes. We think it’s accurate to consider it a novel immune checkpoint – a completely natural mechanism that can have a profound effect on tumor etiology, without significant toxicity.” Yates continued, “We demonstrated that both in vitro and in vivo, the RP class of peptides are able to repolarize the macrophage population, and that once repolarized, the macrophages return to phagocytic activity and begin consuming cancer cells. They also send downstream signals to the T-cell, NK-cell and B-cell populations to attack the tumor.” Riptide President Dr. George Martin commented, “The results in animal models of organ cancers have been spectacular. RP-182, administered in combination with gemcitabine, produced the best results ever shown in NCI’s KRAS-p16 pancreatic cancer model. Also, with its distinctive mechanism, it has been shown to powerfully complement both chemotherapy and checkpoint inhibitor immunotherapy.” Dr. Martin continued, “Riptide has built very solid intellectual property around this program, and following the promising early work with RP-182, has developed two other peptide candidates with even better efficacy and excellent pharmacokinetics. These have demonstrated striking results in preclinical models of colon, breast, prostate, and skin cancers.“ Riptide Executive Vice President Dr. Henry Lopez added, “Also, since M2 macrophages are important in the progress of certain fibroses, including scleroderma and IPF, we anticipated – and have recently confirmed – potent efficacy in animal models of those diseases.” Dr. Martin concluded, “We’re now engaging with larger pharmaceutical companies to move this important program into clinic. I see a real opportunity, similar in many ways to the discovery of the first checkpoint inhibitors, to make a major impact on clinical practice.” Riptide Bioscience, Inc., with laboratories in Vallejo, California, maintains an intensive program of research into peptide-based therapeutics. View source version on businesswire.com: Charles Garvin, CEO, cgarvin@riptidebio.com NEXT ARTICLE More From BioPortfolio on "Riptide Bioscience Announces Discovery of Novel Immune Checkpoint" Related Companies Related Clinical Trials Related PubMed Entries Related Medications

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100 Deals associated with Anti-cancer peptides(Riptide Bioscience, Inc.)

R&D Status

10 top R&D records.

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Indication	Highest Phase	Country/Location	Organization	Date
Pancreatic Cancer	Preclinical	United States	National Cancer Institute	-
Pancreatic Cancer	Preclinical	United States	Riptide Bioscience, Inc.	-

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