Comparison of the interactions of daunorubicin in a free form and attached to single-walled carbon nanotubes with model lipid membranes

Matyszewska, Dorota

doi:10.3762/bjnano.7.46

Cited by 8 publications

(4 citation statements)

References 35 publications

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“…Such high concentrations of positively charged drugs at the water-interface of the bilayer can alter the delicate electrostatic balance in the lipid headgroups, inducing repulsion between the choline groups of phospholipids and increasing the distance between neighbor lipids (area per lipid), which results in a marked increase in membrane fluidity [83]. The latter is in complete concordance with reports of increased membrane fluidity induced by SUN, SIR [22] and DNR [84], as well as with the observed LMP induced by LDs [85]. In both cases, the fluidization effect was pH-dependent, a finding that correlates with the current results, where the abundance of LDs at the water/membrane interface was more prominent at acidic pH, where all compounds have the highest charge due to immediate protonation.…”

Section: Discussionsupporting

confidence: 85%

The Lysosomotropic Activity of Hydrophobic Weak Base Drugs is Mediated via Their Intercalation into the Lysosomal Membrane

Stark

Silva

Levin

et al. 2020

Cells

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Lipophilic weak base therapeutic agents, termed lysosomotropic drugs (LDs), undergo marked sequestration and concentration within lysosomes, hence altering lysosomal functions. This lysosomal drug entrapment has been described as luminal drug compartmentalization. Consistent with our recent finding that LDs inflict a pH-dependent membrane fluidization, we herein demonstrate that LDs undergo intercalation and concentration within lysosomal membranes. The latter was revealed experimentally and computationally by (a) confocal microscopy of fluorescent compounds and drugs within lysosomal membranes, and (b) molecular dynamics modeling of the pH-dependent membrane insertion and accumulation of an assortment of LDs, including anticancer drugs. Based on the multiple functions of the lysosome as a central nutrient sensory hub and a degradation center, we discuss the molecular mechanisms underlying the alteration of morphology and impairment of lysosomal functions as consequences of LDs’ intercalation into lysosomes. Our findings bear important implications for drug design, drug induced lysosomal damage, diseases and pertaining therapeutics.

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Section: Discussionsupporting

confidence: 85%

The Lysosomotropic Activity of Hydrophobic Weak Base Drugs is Mediated via Their Intercalation into the Lysosomal Membrane

Stark

Silva

Levin

et al. 2020

Cells

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“…Hence, these findings confirm that PC-Im enhanced lysosomal fusion, resulting in rapid enlargement of lysosomes and decreased numbers of lysosomes per cell. Taking together the key role of membrane fluidity in the fusion of cells and organelles , along with several publications that demonstrated increased lysosomal membrane fluidity upon treatment with lysosomotropic agents, , we propose that PC-Im accumulates in the membrane of lysosomes where it induces increased membrane fluidity, resulting in enhanced lysosomal fusion. Since fusion processes rely on SNAREs, some of which depend on calcium, we further considered that upon lysosomal accumulation of PC-Im , calcium is released from lysosomes, thereby enhancing lysosome fusion via lysosomal SNAREs. − An attractive possibility is that upon accumulation of PC-Im in the membrane of lysosomes, and to a lesser extent in the membranes of the ER and Golgi apparatus, PC-Im provokes enhanced membrane fluidity and calcium leakage to the cytoplasm.…”

Section: Results and Discussionmentioning

confidence: 70%

Doubly Stimulated Corrole for Organelle-Selective Antitumor Cytotoxicity

et al. 2022

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Balancing between safety and efficacy of cancer chemotherapeutics is achievable by relying on internal and/or external stimuli for selective and on-demand antitumor cytotoxicity. We now introduce the difluorophosphorus(V) corrole PC-Im, a theranostic agent with a pH-sensitive N-methylimidazole moiety. Structure/activity relationships, via comparison with the permanently charged PC-ImM + and the lipophilic PC, uncovered the exceptional features of PC-Im: nanoparticular and monomeric at neutral and low pH, respectively, 10-fold increased light-induced singlet oxygen production at acidic pH, internalization into malignant cells within minutes, and selective accumulation within lysosomes. Submillimolar PC-Im concentrations are tolerable in the dark, while illumination induces nanomolar cytotoxic effects due to a multiplicity of cellular deleterious events: endoplasmic reticulum fragmentation, lysosome fusion and exocytosis, calcium leakage, mitochondrial fission, and swelling. PC-Im emerges as an antitumor agent, whose potency is triggered by endogenous and exogenous stimuli, assuring its cytotoxicity will occur selectively upon lysosomal accumulation and solely upon light activation.

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“…The loading of active ingredients in liposomes can ensure optimum efficacy, enhance specific targeting and reduce toxicity. Liposomes can carry both lipophilic and hydrophilic drugs which can improve the efficiency of the treatment [24]. In this study, four anticancer drugs were selected based on their log P values ranging from log P = -3 to log P = ?…”

Section: Encapsulation Efficiencymentioning

confidence: 99%

Development and Characterization of DOPEPEG2000 Coated Oleic Acid Liposomes Encapsulating Anticancer Drugs

Suk

Misran

2016

J Surfact & Detergents

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Liposomes have been widely investigated as drug carriers for a broad range of anticancer drugs. However, their application as a drug delivery system may be challenging due to low encapsulation of active ingredient and poor stability which leads to uncontrolled delivery of bioactive ingredients. The present study aims at incorporating 1,2‐dioleoyl‐sn‐glycero‐3‐phosphoethanolamide‐N‐[methoxy(polyethylene glycol)‐2000 (DOPEPEG2000) into oleic acid (OA) liposomes in order to prolong the lifetime in blood circulation. The pH transition curve of oleic was obtained by titration of sodium oleate solution with 0.05 mol dm−3 HCl to determine the region where liposomes were abundantly present. The critical vesicle concentration (CVC) was then determined by surface tension measurements. Dry lipid liposomes were hydrated with phosphate buffer at just over twice the CVC value. Optical polarizing microscopy (OPM) showed the presence of liposomes while transmission electron microscopy (TEM) confirmed that the liposomes prepared were spherical in shape and less than 200 nm in size. The incorporation of DOPEPEG2000 into the oleic acid liposomes reduced the average particle size and zeta potential to mimic the red blood cells. The encapsulation efficiency of various anticancer drugs was more than 60% while more than 20% of the drugs were released after 24 h. The results suggest that DOPEPEG2000: oleic acid at a molar ratio of 1:50 fulfilled the requirements for intravenous drug delivery.

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Comparison of the interactions of daunorubicin in a free form and attached to single-walled carbon nanotubes with model lipid membranes

Cited by 8 publications

References 35 publications

The Lysosomotropic Activity of Hydrophobic Weak Base Drugs is Mediated via Their Intercalation into the Lysosomal Membrane

The Lysosomotropic Activity of Hydrophobic Weak Base Drugs is Mediated via Their Intercalation into the Lysosomal Membrane

Doubly Stimulated Corrole for Organelle-Selective Antitumor Cytotoxicity

Development and Characterization of DOPEPEG2000 Coated Oleic Acid Liposomes Encapsulating Anticancer Drugs

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