Liposome-based Drug Research Articles

The electro-responsive nanoliposome as an on-demand drug delivery platform for epilepsy treatment

Nano-based drug delivery systems are regarded as a promising tool for efficient epilepsy treatment and seizure medication with the least general side effects and socioeconomic challenges. In the current study, we have designed a smart nanoscale drug delivery platform and applied it in the kindling model of epilepsy that is triggered rapidly by epileptic discharges and releases anticonvulsant drugs in situ, such as carbamazepine (CBZ). The CBZ-loaded electroactive ferrocene nanoliposomes had an average diameter of 100.6 nm, a surface charge of −7.08 mV, and high drug encapsulation efficiency (85.4 %). A significant increase in liposome size was observed in response to direct current (50–500 μA) application. This liposome-based drug delivery system can release CBZ at a fast rate in response to both direct current and pulsatile electrical stimulation in vitro. The CBZ-liposome can release the anticonvulsant drug upon epileptiform activity in the kindled rat model and can decline electrographic and behavioral seizure activity in response to electrical stimulation of the hippocampus with an initially subconvulsive current. With satisfactory biosafety results, this “smart” nanocarrier has promising potential as an effective and safe drug delivery system to improve the therapeutic index of antiepileptic drugs.

Preparation and evaluation of liposomal gel containing Neolamarckia cadamba leaves extract for anti-inflammatory activity

The objective of present research work is to develop liposomes as a carrier system for methanolic extract, its incorporation in to gel formulations and to characterize the prepared and develop liposomal gel formulation. Formulation was carried out by thin film technique. Scanning electron micrograph of the prepared nanosponges at 50.00 kx magnification showed that the liposome was porous with a smooth surface morphology and spherical shape. The porous nature of liposome was clearly observed in the SEM images. Particle size and zeta potential was determined by Malvern Zeta sizer. The particle size analysis confirmed that the prepared sample were in the nanometer range. Average particle size obtained for the formulations F1 to F5 were 162.7 nm to 195.6 nm. Zeta potential values of liposome indicated that the formulated liposomes are stable. The amount of drug being entrapped in liposome was calculated and all the prepared liposome was found to possess very high entrapment efficiency. The viscosity of liposome loaded gel is found to 6842±0.32cps. The pH of liposome loaded gel is 6.3 and spreadability is 12.11, indicating that liposome loaded gel has high release and permeability. The in vitro anti-inflammatory effect of Neolamarckia cadamba extract was evaluated against denaturation of egg albumin. The present findings exhibited a concentration dependent inhibition of protein (albumin) denaturation by Neolamarckia cadamba throughout the concentration range of 20-100μg/ml. Diclofenac sodium (at the concentration range of 20-100 μg/ml) was used as reference drug which also exhibited concentration dependent inhibition of protein denaturation; however, the effect of diclofenac sodium was found to be less active when compared with extract name. Moreover, the results demonstrated that the liposome-based drug delivery approach could be a valuable tool to improve the therapeutic efficacy of phytochemicals by improving their absorption, and bioavailability via altering their physicochemical and release properties. Keywords: Liposomes, Neolamarckia cadamba, Qualitative phytochemical screening, Thin film technique, In vitro anti-inflammatory activity.

Molecular Dynamics Simulations Reveal Octanoylated Hyaluronic Acid Enhances Liposome Stability, Stealth and Targeting.

Liposome-based drug delivery systems have been widely used in drug and gene delivery. However, issues such as instability, immune clearance, and poor targeting have significantly limited their clinical utility. Consequently, there is an urgent need for innovative strategies to improve liposome performance. In this study, we explore the interaction mechanisms of hyaluronic acid (HA), a linear anionic polysaccharide composed of repeating disaccharide units of d-glucuronic acid and N-acetyl-d-glucosamine connected by alternating β-1,3 and β-1,4 glycosidic linkages, and its octanoylated derivates (OHA) with liposomes using extensive coarse-grained molecular dynamics simulations. The octyl moieties of OHA spontaneously inserted into the phospholipid bilayer of liposomes, leading to their effective coating onto the surface of liposome and enhancing their structural stability. Furthermore, encapsulating liposome with OHA neutralized their surface potential, interfering with the formation of a protein corona known to contribute to liposomal immune clearance. Importantly, the encapsulated OHA maintained its selectivity and therefore targeting ability for CD44, which is often overexpressed in tumor cells. These molecular-scale findings shed light on the interaction mechanisms between HA and liposomes and will be useful for the development of next-generation liposome-based drug delivery systems.

A comprehensive review on Liposomes: As a novel drug delivery system

Liposomes, as versatile lipid-based nanoparticles, have emerged as promising drug delivery systems in recent years. This comprehensive review aims to provide an in-depth analysis of the advancements, challenges, and potential applications of liposomes in drug delivery. The review covers various aspects of liposome-based drug delivery, including their structure, formulation methods, advantages, limitations, and recent breakthroughs in the field. Furthermore, we discuss the diverse range of drugs and therapeutic agents that can be encapsulated within liposomes, as well as their clinical applications in targeting specific diseases.

An updated review on liposomes

Liposomes, tiny bubbles made from the same material as a cell membrane, are considered the most successful nanocarriers for drug delivery. They are biocompatible and stable, encapsulating both hydrophilic and lipophilic drugs and protecting them from degradation. Liposomes are the most commonly used drug delivery vehicles due to their high drug trapping capacity and efficiency. These offer controlled release, targeted drug delivery, increased therapeutic efficacy, and reduced dosing frequency. Liposome-based drug formulations have been approved for clinical use and are the subject of extensive research. Recent liposomal formulations aim to reduce toxicity and increase target site accumulation. With numerous advantages, liposomes prove their uniqueness in safe drug delivery in various areas of pharmacy and medicine. We will keep an eye on overall updated review on liposomes classification, their structural components, mechanism of action, stability, method of preparation, their evaluation tests and applications.

Liposome-Based Drug Delivery Systems in Cancer Research: An Analysis of Global Landscape Efforts and Achievements.

Lipid-bilayer-based liposomes are gaining attention in scientific research for their versatile role in drug delivery. With their amphiphilic design, liposomes efficiently encapsulate and deliver drugs to targeted sites, offering controlled release. These artificial structures hold great promise in advancing cancer therapy methodologies. Bibliometric research analyzes systematic literary data statistically. This study used bibliometric indicators to examine, map, and evaluate the applications of liposomes in cancer therapy. A Scopus search was conducted to identify all English-language peer-reviewed scientific publications on the applications of liposomes in cancer therapy within the past twenty years. Bibliometric indicators were calculated using VOSviewer and Biblioshiny. We produced thematic, conceptual, and visualization charts. A total of 14,873 published documents were obtained. The procedure of keyword mapping has effectively identified the main areas of research concentration and prevailing trends within this specific field of study. The significant clusters discovered through theme and hotspot analyses encompassed many topics such as the use of multiple strategies in chemotherapy and different forms of cancer, the study of pharmacokinetics and nanomedicine, as well as the investigation of targeted drug delivery, cytotoxicity, and gene delivery. Liposomes were employed as drug delivery systems so as to selectively target cancer cells and improve the bioavailability of anticancer drugs. The work showcased the capacity to tailor these liposomes for accurate drug delivery by including potent anticancer medications. Our findings not only bring attention to the latest progress in utilizing liposomes for cancer treatment but also underscore the vital need for ongoing research, collaborative efforts, and the effective translation of these breakthroughs into tangible clinical applications, emphasizing the dynamic and evolving nature of cancer therapeutics.

Engineered triphenylphosphonium-based, mitochondrial-targeted liposomal drug delivery system facilitates cancer cell killing actions of chemotherapeutics.

In addition to their classical role in ATP generation, mitochondria also contribute to Ca2+ buffering, free radical production, and initiation of programmed cell death. Mitochondrial dysfunction has been linked to several leading causes of morbidity and mortality worldwide including neurodegenerative, metabolic, and cardiovascular diseases as well as several cancer subtypes. Thus, there is growing interest in developing drug-delivery vehicles capable of shuttling therapeutics directly to the mitochondria. Here, we functionalized the conventional 10,12-pentacosadiynoic acid/1,2-dimyristoyl-sn-glycero-3-phosphocholine (PCDA/DMPC)-based liposome with a mitochondria-targeting triphenylphosphonium (TPP) cationic group. A fluorescent dansyl dye (DAN) group was also included for tracking mitochondrial drug uptake. The resultant PCDA-TPP and PCDA-DAN conjugates were incorporated into a 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC)-based lipid bilayer, and these modified liposomes (Lip-DT) were studied for their cellular toxicity, mitochondrial targeting ability, and efficacy in delivering the drug Doxorubicin (Dox) to human colorectal carcinoma (HCT116) and human breast (MCF7) cancer cells in vitro. This Lip-DT-Dox exhibited the ability to shuttle the encapsulated drug to the mitochondria of cancer cells and triggered oxidative stress, mitochondrial dysfunction, and apoptosis. The ability of Lip-DT-Dox to trigger cellular toxicity in both HCT116 and MCF7 cancer cells was comparable to the known cell-killing actions of the unencapsulated drug (Dox). The findings in this study reveal a promising approach where conventional liposome-based drug delivery systems can be rendered mitochondria-specific by incorporating well-known mitochondriotropic moieties onto the surface of the liposome.

Aromatized liposomes for sustained drug delivery

Insufficient drug loading and leakage of payload remain major challenges in designing liposome-based drug delivery systems. These phenomena can limit duration of effect and cause toxicity. Targeting the rate-limiting step in drug release from liposomes, we modify (aromatized) them to have aromatic groups within their lipid bilayers. Aromatized liposomes are designed with synthetic phospholipids with aromatic groups covalently conjugated onto acyl chains. The optimized aromatized liposome increases drug loading and significantly decreases the burst release of a broad range of payloads (small molecules and macromolecules, different degrees of hydrophilicity) and extends their duration of release. Aromatized liposomes encapsulating the anesthetic tetrodotoxin (TTX) achieve markedly prolonged effect and decreased toxicity in an application where liposomes are used clinically: local anesthesia, even though TTX is a hydrophilic small molecule which is typically difficult to encapsulate. Aromatization of lipid bilayers can improve the performance of liposomal drug delivery systems.

Formulation and Characterization of Griseofulvin Liposome Loaded Topical Film

This research paper explores the formulation and characterization of a liposome-loaded topical film containing griseofulvin, an antifungal drug. Liposome-based drug delivery systems offer enhanced drug concentration, prolonged residence time, and reduced side effects. This study aims to improve the efficacy of griseofulvin by incorporating it into liposomes and formulating it into a topical film for transdermal delivery. Liposomes were used as carriers to encapsulate Griseofulvin and incorporated into a topical film for ease of application. The paper reviews the principles of liposome-based drug delivery, transdermal film technology, and the potential benefits of this approach. The work plan includes preformulation studies, liposome preparation and evaluation, formulation of liposome-loaded topical films, and evaluation of film properties. The results demonstrated that the developed formulation has the potential to improve the delivery and efficacy of Griseofulvin in the treatment of cutaneous fungal infections.

NANOPARTICLE BASED DRUG DELIVERY SYSTEMS FOR TARGETING TUMOR MICRO ENVIRONMENT

Nanoparticle-based drug delivery systems have emerged as promising tools in cancer therapy, offering enhanced precision and effectiveness in targeting tumor cells while minimizing damage to healthy tissues. This review provides a comprehensive exploration of the tumor microenvironment, emphasizing its critical role in cancer progression. It highlights the significance of targeted drug delivery in improving treatment outcomes and introduces nanoparticle-based delivery systems as innovative strategies to address these challenges. The first section delves into various types of nanoparticles used for tumor targeting. Liposomes, known for their versatility and biocompatibility, are discussed alongside examples of liposome-based drug delivery systems tailored for tumor-specific applications. Polymeric nanoparticles, employing a range of polymers, offer unique advantages and applications in tumor targeting. Metallic nanoparticles, with distinctive properties, have shown promise in drug delivery systems designed to target tumors effectively.

Advanced treatment strategies in breast cancer: A comprehensive mechanistic review.

Breast cancer is a destructive lump type that affects women globally. Despite the availability of multi-directional therapeutic strategies, advanced stages of breast cancer are difficult to treat and impose major healthcare burdens. This situation reinforces the need to identify new potential therapeutic compounds with better clinical features. In this context, different treatment methods were included such as Endocrine therapy, chemotherapy, Radiation therapy, antimicrobial peptide-dependent growth inhibitor, liposome-based drug delivery, antibiotics used as a co-medication, photothermal, immunotherapy, and nano drug delivery systems such as Bombyx mori natural protein sericin and its mediated nanoparticles are promising biomedical agents. They have been tested as an anticancer agent against various malignancies in pre-clinical settings. The biocompatible and restricted breakdown properties of silk sericin and sericin-conjugated nanoparticles made them perfect contenders for a nanoscale drug-delivery system.

Multiple CEST contrast imaging of nose-to-brain drug delivery using iohexol liposomes at 3T MRI.

Image guided nose-to-brain drug delivery provides a non-invasive way to monitor drug delivered to the brain, and the intranasal administration could increase effective dose via bypassing Blood Brain Barrier (BBB). Here, we investigated the imaging of liposome-based drug delivery to the brain via intranasal administration, in which the liposome could penetrate mucus and could be detected by chemical exchange saturation transfer (CEST) magnetic resonance imaging (MRI) at 3T field strength. Liposomes were loaded with a computed tomography (CT) contrast agent, iohexol (Ioh-Lipo), which has specific amide protons exchanging at 4.3ppm of Z-spectrum (or CEST spectrum). Ioh-Lipo generated CEST contrasts of 35.4% at 4.3ppm, 1.8% at -3.4ppm and 20.6% at 1.2ppm in vitro. After intranasal administration, these specific CEST contrasts were observed in both olfactory bulb (OB) and frontal lobe (FL) in the case of 10% polyethylene glycol (PEG) Ioh-Lipo. We observed obvious increases in CEST contrast in OB half an hour after the injection of 10% PEG Ioh-Lipo, with a percentage increase of 62.0% at 4.3ppm, 10.9% at -3.4ppm and 25.7% at 1.2ppm. Interestingly, the CEST map at 4.3ppm was distinctive from that at -3.4pm and 1.2ppm. The highest contrast of 4.3ppm was at the external plexiform layer (EPL) and the region between left and right OB (LROB), while the CEST contrast at -3.4ppm had no significant difference among all investigated regions with slightly higher signal in olfactory limbus (OL, between OB and FL) and FL, as validated with histology. While no substantial increase of CEST contrast at 4.3ppm, -3.4ppm or 1.2ppm was observed in OB and FL when 1% PEG Ioh-Lipo was administered. We demonstrated for the first time the feasibility of non-invasively detecting the nose-to-brain delivery of liposomes using CEST MRI. This multiple-contrast approach is necessary to image the specific distribution of iohexol and liposome simultaneously and independently, especially when designing drug carriers for nose-to-brain drug delivery.

Insights into Asymmetric Liposomes as a Potential Intervention for Drug Delivery Including Pulmonary Nanotherapeutics

Liposome-based drug delivery systems are nanosized spherical lipid bilayer carriers that can encapsulate a broad range of small drug molecules (hydrophilic and hydrophobic drugs) and large drug molecules (peptides, proteins, and nucleic acids). They have unique characteristics, such as a self-assembling bilayer vesicular structure. There are several FDA-approved liposomal-based medicines for treatment of cancer, bacterial, and viral infections. Most of the FDA-approved liposomal-based therapies are in the form of conventional "symmetric" liposomes and they are administered mainly by injection. Arikace® is the first and only FDA-approved liposomal-based inhalable therapy (amikacin liposome inhalation suspension) to treat only adults with difficult-to-treat Mycobacterium avium complex (MAC) lung disease as a combinational antibacterial treatment. To date, no "asymmetric liposomes" are yet to be approved, although asymmetric liposomes have many advantages due to the asymmetric distribution of lipids through the liposome's membrane (which is similar to the biological membranes). There are many challenges for the formulation and stability of asymmetric liposomes. This review will focus on asymmetric liposomes in contrast to conventional liposomes as a potential clinical intervention drug delivery system as well as the formulation techniques available for symmetric and asymmetric liposomes. The review aims to renew the research in liposomal nanovesicle delivery systems with particular emphasis on asymmetric liposomes as future potential carriers for enhancing drug delivery including pulmonary nanotherapeutics.

Interaction of Phospholipid, Cholesterol, Beta-Carotene, and Vitamin C Molecules in Liposome-Based Drug Delivery Systems: An In Silico Study.

This paper investigates the interaction within a liposome-based drug delivery system in silico. Results confirmed that phospholipids, cholesterol, beta-carotene, and vitamin C in the liposome structures interact noncovalently. The formation of noncovalent interactions indicates that the liposomal structures from phospholipid molecules will not result in chemical changes to the drug or any molecules encapsulated within. Noncovalent interactions formed include (i) moderate-strength hydrogen bonds with interaction energies ranging from -73.6434 kJ·mol-1 to -45.6734 kJ·mol-1 and bond lengths ranging from 1.731 Å to 1.827 Å and (ii) van der Waals interactions (induced dipole-induced dipole and induced dipole-dipole interactions) with interaction energies ranging from -4.4735 kJ·mol-1 to -1.5840 kJ·mol-1 and bond lengths ranging from 3.192 Å to 3.742 Å. The studies for several phospholipids with short hydrocarbon chains show that changes in chain length have almost no effect on interaction energy, bond length, and partial atomic charge.

Effective combination of liposome-targeted chemotherapy and PD-L1 blockade of murine colon cancer.

Therapeutic cancer drug efficacy can be limited by insufficient tumor penetration, rapid clearance, systemic toxicity and (acquired) drug resistance. The poor therapeutic index due to inefficient drug penetration and rapid drug clearance and toxicity can be improved by using a liposomal platform. Drug resistance for instance against pemetrexed, can be reduced by combination with docetaxel. Here, we developed a specific liposomal formulation to simultaneously deliver docetaxel and pemetrexed to enhance efficacy and safety. Hydrophobic docetaxel and hydrophilic pemetrexed were co-encapsulated into pH-sensitive liposomes using a thin-film hydration method with high efficiency. The physicochemical properties, toxicity, and immunological effects of liposomes were examined in vitro. Biodistribution, anti-tumor efficacy, and systemic immune response were evaluated in vivo in combination with PD-L1 immune checkpoint therapy using two murine colon cancer models. In cellular experiments, the liposomes exhibited strong cytotoxicity and induced immunogenic cell death. In vivo, the treatment with the liposome-based drug combination inhibited tumor development and stimulated immune responses. Liposomal encapsulation significantly reduced systemic toxicity compared to the delivery of the free drug. Tumor control was strongly enhanced when combined with anti-PDL1 immunotherapy in immunocompetent mice carrying syngeneic MC38 or CT26 colon tumors. We showed that treatment with liposome-mediated chemotherapy of docetaxel and pemetrexed combined with anti-PD-L1 immunotherapy is a promising strategy for the treatment of colon cancers.

Perspective on the Application of Erythrocyte Liposome-Based Drug Delivery for Infectious Diseases.

Nanoparticles are explored as drug carriers with the promise for the treatment of diseases to increase the efficacy and also reduce side effects sometimes seen with conventional drugs. To accomplish this goal, drugs are encapsulated in or conjugated to the nanocarriers and selectively delivered to their targets. Potential applications include immunization, the delivery of anti-cancer drugs to tumours, antibiotics to infections, targeting resistant bacteria, and delivery of therapeutic agents to the brain. Despite this great promise and potential, drug delivery systems have yet to be established, mainly due to their limitations in physical instability and rapid clearance by the host's immune response. Recent interest has been taken in using red blood cells (RBC) as drug carriers due to their naturally long circulation time, flexible structure, and direct access to many target sites. This includes coating of nanoparticles with the membrane of red blood cells, and the fabrication and manipulation of liposomes made of the red blood cells' cytoplasmic membrane. The properties of these erythrocyte liposomes, such as charge and elastic properties, can be tuned through the incorporation of synthetic lipids to optimize physical properties and the loading efficiency and retention of different drugs. Specificity can be established through the anchorage of antigens and antibodies in the liposomal membrane to achieve targeted delivery. Although still at an early stage, this erythrocyte-based platform shows first promising results in vitro and in animal studies. However, their full potential in terms of increased efficacy and side effect minimization still needs to be explored in vivo.

Interaction of GC376, a SARS-COV-2 MPRO inhibitor, with model lipid membranes

Partitioning and effect of antiviral GC376, a potential SARS-CoV-2 inhibitor, on model lipid membranes was studied using dynamic light scattering (DLS), UV–VIS spectrometry, Excimer fluorescence, Differential scanning calorimetry (DSC) and Small- and Wide-angle X-ray scattering (SAXS/WAXS). Partition coefficient of GC376 between lipid and water phase was found to be low, reaching KP = 46.8 ± 18.2. Results suggest that GC376 partitions into lipid bilayers at the level of lipid head-groups, close to the polar/hydrophobic interface. Changes in structural and thermodynamic properties strongly depend on the GC376/lipid mole ratio. Already at lowest mole ratios GC376 induces increase of lateral pressures, mainly in the interfacial region of the bilayer. Hereby, the pre- and main-transition temperature of the lipid system increases, what is attributed to tighter packing of acyl chains induced by GC376. At GC376/DPPC ≥ 0.03 mol/mol we detected formation of domains with different GC376 content resulting in the lateral phase separation and changes in both, main transition temperature and enthalpy. The observed changes are attributed to the response of the system on the increased lateral stresses induced by partitioning of GC376. Obtained results are discussed in context of liposome-based drug delivery systems for GC376 and in context of indirect mechanism of virus replication inhibition.

Spotlight on Photoactivatable Liposomes beyond Drug Delivery: An Enabler of Multitargeting of Molecular Pathways.

The potential of photoactivating certain molecules, photosensitizers (PS), resulting in photochemical processes, has long been realized in the form of photodynamic therapy (PDT) for the management of several cancerous and noncancerous pathologies. With an improved understanding of the photoactivation process and its broader implications, efforts are being made to exploit the various facets of photoactivation, PDT, and the associated phenomenon of photodynamic priming in enhancing treatment outcomes, specifically in cancer therapeutics. The parallel emergence of nanomedicine, specifically liposome-based nanoformulations, and the convergence of the two fields of liposome-based drug delivery and PDT have led to the development of unique hybrid systems, which combine the exciting features of liposomes with adequate complementation through the photoactivation process. While initially liposomes carrying photosensitizers (PSs) were developed for enhancing the pharmacokinetics and the general applicability of PSs, more recently, PS-loaded liposomes, apart from their utility in PDT, have found several applications including enhanced targeting of drugs, coloading multiple therapeutic agents to enhance synergistic effects, imaging, priming, triggering drug release, and facilitating the escape of therapeutic agents from the endolysosomal complex. This review discusses the design strategies, potential, and unique attributes of these hybrid systems, with not only photoactivation as an attribute but also the ability to encapsulate multiple agents for imaging, biomodulation, priming, and therapy referred to as photoactivatable multiagent/inhibitor liposomes (PMILS) and their targeted versions─targeted PMILS (TPMILS). While liposomes have formed their own niche in nanotechnology and nanomedicine with several clinically approved formulations, we try to highlight how using PS-loaded liposomes could address some of the limitations and concerns usually associated with liposomes to overcome them and enhance their preclinical and clinical utility in the future.

Regulatory Considerations Specific to Liposome Drug Development as Complex Drug Products

Nearly a half-century after original liposome discovery as a prospective lipid pharmaceutical carrier, the global liposomal drug delivery market has increased dramatically, with an annual market growth rate of 13.2%, valued at ∼$6,993 million by 2027. As an intrinsically complex delivery system, liposomal formulations face much greater characterization and regulatory review challenges than traditional small molecule drugs and biologics. Due to rapid liposomal drug development, both European Medicines Agency (EMA) and US Food and Drug Administration (FDA) now provide regulatory guidance for new liposomal drug application reviews. The expanding global liposome drug market and associated driving forces for increased research and development (R&D) in novel liposomal products are key factors propelling liposomal drug interests. We review and compare EU and US regulations on liposomal drug submissions, and provide insights into regulatory strategies throughout the entire liposomal drug development process. This addresses current gaps noted between liposome-based drug development in research labs and current regulatory guidance for liposomal drug approvals in order to facilitate more efficient, less costly, and less risky complex drug development.

Peptide-Folding Triggered Phase Separation and Lipid Membrane Destabilization in Cholesterol-Rich Lipid Vesicles

Liposome-based drug delivery systems are widely used to improve drug pharmacokinetics but can suffer from slow and unspecific release of encapsulated drugs. Membrane-active peptides, based on sequences derived or inspired from antimicrobial peptides (AMPs), could offer means to trigger and control the release. Cholesterol is used in most liposomal drug delivery systems (DDS) to improve the stability of the formulation, but the activity of AMPs on cholesterol-rich membranes tends to be very low, complicating peptide-triggered release strategies. Here, we show a de novo designed AMP-mimetic peptide that efficiently triggers content release from cholesterol-containing lipid vesicles when covalently conjugated to headgroup-functionalized lipids. Binding to vesicles induces peptide folding and triggers a lipid phase separation, which in the presence of cholesterol results in high local peptide concentrations at the lipid bilayer surface and rapid content release. We anticipate that these results will facilitate the development of peptide-based strategies for controlling and triggering drug release from liposomal drug delivery systems.