Machine learning and mapping algorithms applied to proteomics problems

Sanders, William Shane

30 April 2011

Proteins provide evidence that a given gene is expressed, and machine learning algorithms can be applied to various proteomics problems in order to gain information about the underlying biology. This dissertation applies machine learning algorithms to proteomics data in order to predict whether or not a given peptide is observable by mass spectrometry, whether a given peptide can serve as a cell penetrating peptide, and then utilizes the peptides observed through mass spectrometry to aid in the structural annotation of the chicken genome. Peptides observed by mass spectrometry are used to identify proteins, and being able to accurately predict which peptides will be seen can allow researchers to analyze to what extent a given protein is observable. Cell penetrating peptides can possibly be utilized to allow targeted small molecule delivery across cellular membranes and possibly serve a role as drug delivery peptides. Peptides and proteins identified through mass spectrometry can help refine computational gene models and improve structural genome annotations.

machine learning

proteomics

mapping algorithms

cell penetrating peptides

peptide observability

proteogenomic mapping

chicken

Biophysical studies of peptides with functions in biotechnology and biology

Madani, Fatemeh

January 2012

My thesis concerns spectroscopic studies (NMR, CD and fluorescence) of peptides with functions in biotechnology and biology, and their interactions with a model membrane (large unilamellar phospholipid vesicles). The resorufin-based arsenical hairpin binder (ReAsH) bound to a short peptide is a useful fluorescent tag for genetic labeling of proteins in living cells. A hairpin structure with some resemblance to type II β-turn was determined by NMR structure calculations (Paper I). Cell-penetrating peptides (CPPs) are short (30-35 residues), often rich in basic amino acids such as Arg. They can pass through the cell membrane and deliver bioactive cargoes, making them useful for biotechnical and pharmacological applications. The mechanisms of cellular uptake and membrane translocation are under debate. Understanding the mechanistic aspects of CPPs is the major focus of Papers II, III, and IV. The effect of the pyrenebutyrate (PB) on the cellular uptake, membrane translocation and perturbation of several CPPs from different subgroups was investigated (Paper II). We concluded that both charge and hydrophobicity of the CPP affect the cellular uptake and membrane translocation efficiency. Endosomal escape is a crucial challenge for the CPP applications. We modeled the endosome and endosomal escape for different CPPs to investigate the corresponding molecular mechanisms (Papers III and IV). Hydrophobic CPPs were able to translocate across the model membrane in the presence of a pH gradient, produced by bacteriorhodopsin proton pumping, whereas a smaller effect was observed for hydrophilic CPPs. Dynorphin A (Dyn A) peptide mutations are associated with neurodegenerative disorders, without involvement of the opioid receptors. The non-opioid activities of Dyn A may involve membrane perturbations. Model membrane-perturbations by three Dyn A mutants were investigated (Paper V). The results showed effects to different degrees largely in accordance with their neurotoxic effects. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript.</p>

Genetic fluorescence label

Biarsenical tetracysteine motif

Cell-penetrating peptides

Large unilamellar vesicles

Pyrenebutyrate

Endosomal escape

Membrane perturbation

Bacteriorhodopsin

Dynorphin

Can exosomes be used as drug delivery vesicles?

Cooke, Fiona Ghina Mary

January 2018

The inflammatory arthritis Ankylosing Spondylitis (AS) is linked to the human leucocyte antigen HLA-B27. HLA-B27 is thought to drive AS because it misfolds during assembly in the endoplasmic reticulum (ER), inducing ER cell stress. Modulating HLA-B27 folding in the ER is therefore a therapeutic target pathway. The recent discovery of polymorphisms in the ER-resident peptidase ERAP1 that can impact on HLA-B27 and AS, makes ERAP1 one such target. Exosomes are small, typically 50-200 nm sized particles, formed in the endosomal recycling pathway, which can be released into the extracellular environment. Exosomes have a wide range of biological activities depending on the cell type of origin, and on the delivered cargo, which can include bio-active proteins, lipids, mRNA and miRNA. There is interest in the use of exosomes as drug delivery agents. Here, exosomes were studied as a delivery agent to modulate ERAP1, as a potential therapeutic tool for the treatment of AS. Exosomes, isolated from cell lines including CEM and Jurkat (T cell lineage), Jesthom (B cell lineage), U937 (monocyte lineage) and the epithelial HeLa cell line, were characterized by nanoparticle tracking analysis, flow cytometry and immunoblotting using markers including CD9, CD63, CD81 and TSG101. Differential expression of these markers in the immune cell lines indicated the complexity of defining exosomes. EVs were then tested using cell penetrating peptides, electroporation, lipid transfection and sonication for their ability to load FITC-siRNA or FITC-antibody as cargo. Significantly, post-loading RNase A or trypsin incubation demonstrated that many techniques do not lead to efficient cargo loading of exosomes. Sonication proved the most effective technique, with up to 30% efficiency. Loading of exosomes with ERAP1-targetted siRNA did not however lead to notable ERAP1 inhibition. The data indicates that external loading of exosomes with cargo remains a significant challenge in developing exosomes as therapeutic tools.

Caractérisation et optimisation des nanoparticules CADY/siRNA en vue d’une application in vivo / Characterization and optimization of CADY/siRNA nanoparticles for an in vivo application

Konate, Karidia

27 May 2015

Les « cell penetrating peptides » (CPPs) sont des vecteurs peptidiques capables de délivrer diverses molécules (acides nucléiques, protéines, peptides, petites molécules, etc.) à l'intérieur des cellules de mammifères. Notre laboratoire a élaboré le vecteur amphipatique secondaire CADY capable de transporter, indépendamment de toute voie d'endocytose, des molécules thérapeutiques telles que les petits ARN interférents (siRNA). En effet, leur potentiel thérapeutique réside dans leur capacité à inhiber de manière spécifique l'expression de protéines dérégulées dans un cadre pathologique.Le sujet de ma thèse s'est centré sur la caractérisation et l'optimisation des complexes CADY/siRNA. Au cours de mes travaux, nous avons pu mettre en évidence que CADY adoptait une structure en hélice alpha en présence du siRNA ce qui conduit à la formation des nanoparticules. Notre étude a eu pour but d'optimiser la séquence de CADY et de contrôler sa formulation pour permettre le transfert de notre système de vectorisation d'une application in cellulo à une application in vivo. En premier lieu, nous avons mené une étude de relations structure-activité avec six peptides analogues de CADY, en réalisant des mutations sur les résidus tryptophanes (PSF1, PSF2, PSF3 et PSW) et sur la zone initiatrice de l'hélice alpha (PG9, PG16). L'analyse approfondie de ces analogues a permis de confirmer que la limitation du caractère amphipathique et du polymorphisme structural des vecteurs conduisaient à une réduction de l'efficacité d'internalisation. Parmi les 6 analogues, seules les nanoparticules à base de PG9 et PG16 présentent des résultats in cellulo comparables à ceux obtenus avec les nanoparticules CADY/siRNA. A ce jour, la séquence primaire de CADY étant la plus adaptée pour la transfection de siRNA, nous avons établi une procédure de formulation standardisée permettant un autoassemblage CADY/siRNA reproductible et homogène, dont la taille moyenne est de 106 ± 31 nm et l'indice de polydispersité de 0,357 ± 0,053. De plus, nous avons mis en place une procédure d'extrusion/lyophilisation afin de stocker les nanoparticules sous forme de poudre. Celle-ci peut être resuspendue en milieu aqueux sans modifications des propriétés colloïdales des nanoparticules ni de leur capacité de transfection.Dans le but d'améliorer la spécificité tissulaire et la biodisponibilité des nanoparticules CADY/siRNA pour une application in vivo, nous avons greffé des motifs de ciblage (YIGSR-S) et de furtivité (PEG) sur la séquence de CADY. L'ajout de ces deux entités, de natures très différentes, ne modifie que faiblement les caractéristiques physico-chimiques (ex. taille moyenne des complexes) et biologiques (transfection cellulaire) des nanoparticules. Ces résultats sont très encourageants pour le développement de nanoparticules dites de 3ème génération, sur lesquelles on peut greffer plusieurs sortes de molécules d'intérêts (ciblage, polymère, agent de contraste etc.).L'ensemble des résultats obtenus au cours de ma thèse marque un réel progrès dans l'optimisation de la formulation du vecteur CADY, et nous incitent à exploiter davantage son potentiel pour le transfert de siRNA in vivo. / Cell penetrating peptides (CPPs) are short peptides that can enter many cell types and transduce into cells a wide range of molecular therapeutics (nucleic acid, proteins, peptides, small molecules, etc.). Our laboratory has developed the secondary amphipathic peptide CADY able to promote the transport of small interfering RNA (siRNA) independently of all endocytotic pathways. Indeed, siRNA therapeutic interest lies on its ability to inhibit specifically deregulated proteins in the context of pathology. The subject of my thesis focused on the characterization and optimization of CADY/siRNA complexes. During my work, we have been able to show that CADY adopts a helical structure while interacting with the siRNA leading to the formation of nanoparticles. The goal of my study was to optimize CADY sequence and control its formulation to consider the transferring from an in cellulo to an in vivo application of our vectorization system. First, we conducted a structure-activity study with six analogues by mutating CADY on tryptophane residues (PSF1, 2, 3 and PSW) and in the area initializing helical structure (PG9, PG16). A thorough analysis of these analogues has confirmed that the limitation of the amphipathic character and structural polymorphism is directly related to the reduction of internalization efficiency of our CPPs. Among the six analogues, only PG16/siRNA and PG9/siRNA nanoparticles show in cellulo results equal to those obtained with CADY/siRNA. Based on the fact, that CADY is the most suitable vector for the transfection of therapeutic molecules such as siRNA, we have established a standard formulation procedure to obtain reproducible and homogeneous CADY/siRNA complexes with an average size of 106 ± 31 nm and a polydispersity index of 0.357 ± 0.053. In addition, we have implemented an extrusion/lyophilization step to allow nanoparticle storage as powder, which can be re-suspended in an aqueous solution without losing their colloidal and transfection properties.In order to improve tissue specificity and bioavailability of CADY/siRNA nanoparticles for an in vivo application, we have grafted ether a targeting sequence (YIGSR-S) or a stealth motif (PEG) to the CADY sequence. These two entities of very different nature provoke only few changes in the physicochemical (e.g. average size) and biological (cell transfection) characteristics of the nanoparticles formed with a siRNA. These results are very encouraging for the development of the so-called 3rd nanoparticle generation which includes several kinds of molecules (targeting, polymer, contrast agent etc.).These outcomes mark the real progress in CADY formulation optimization, and encourage us to further exploit its potential for the in vivo transfer of siRNA.

Peptides vecteurs

SiRNA

Interaction lipidique

Formulation

Fonctionnalisation

Nanoparticules

Cell penetrating peptides

SiRNA

Lipidic interaction

Formulation

Functionalization

Nanoparticles

EXPLORING ANTIBIOTIC CONJUGATION TO CATIONIC AMPHIPHILIC POLYPROLINE HELICES

Samantha Mae Zeiders (10010291)

26 April 2021

<p>Pathogenic bacteria present a critical threat to modern medicine. Therapeutic strategies to target and eliminate resilient bacteria are not advancing at the same rate as the emergence of bacterial resistance. An associated urgent concern regarding antibiotic resistance is the existence and proliferation of intracellular bacteria, which find refuge from bactericidal mechanisms by hiding within mammalian cells. Therefore, many once-successful antibiotics become ineffective through the development of resistance, or through failure to reach intracellular locations in therapeutic concentration. To overcome these challenges, the covalent combination of a conventional antibiotic with an antibiotic, cell-penetrating peptide was explored to develop dual-action antibiotic conjugates. </p> <p>Herein, we utilized a strategy in conjugating the antibiotics by a cleavable linkage to cationic amphiphilic polyproline helices (CAPHs) to improve vancomycin and linezolid antibiotics. This approach enables the conjugate to penetrate cells and deliver two potent monomeric antimicrobial drugs. The vancomycin-CAPH conjugate, <b>VanP14S</b>, showed enhanced mammalian cell uptake compared to vancomycin, a poor mammalian cell-penetrating agent; and <b>VanP14S</b> was capable of cleaving and releasing two antibiotics under mimicked physiological conditions. Enhanced antibacterial activity was observed against a spectrum of Gram-positive and Gram-negative pathogens, including drug-resistant strains. Further investigation revealed that this conjugate’s bactericidal activity was not entirely the result of significant membrane perturbation such as a lytic mode of action. Mammalian cell toxicity and red blood cell lysis were insignificant at relevant bactericidal concentrations below 20 µM. The current results suggest an enhanced binding to the peptidoglycan of bacteria, the target of vancomycin, although more work is needed to justify this claim. Preliminary results on <b>VanP14GAPS</b>, a conjugate with a more rigid CAPH, convey similar activity to <b>VanP14S; </b>however,<b> </b>moderate increases in red blood cell lysis and cytotoxicity were observed. </p> <p>Regarding the <b>LnzP14</b> conjugate, preliminary data reveal that the conjugate has Gram-negative activity against <i>Escherichia coli</i>, whereas linezolid is ineffective in killing Gram-negative bacteria. This conjugate showed significant enhancement in cellular uptake compared to the CAPH, and the release of linezolid and CAPH in physiological conditions was confirmed. Overall, arming a conventional antibiotic with an antimicrobial, cell-penetrating peptide appears to be a powerful strategy in providing novel antibiotic conjugates with the propensity to overcome the limitations in treating challenging pathogens.</p>

Organic Chemistry

Biologically Active Molecules

antibacterial

chemical biology

conjugate chemistry

peptide

Cell-Penetrating Peptides

antimicrobial peptides

vancomycin

linezolid

polyproline

Evaluation of mechanisms for accessing intracellular targets for protein-based drugs

Jindi Elias, Sonav

January 2021

Over the years, biological drugs have evolved and have made breakthroughs in diseases associated with extracellular proteins. However, intracellular proteins that cause disease progression are still largely inaccessible. Examples of diseases that are caused by an intracellular aggregation of proteins are neurodegenerative diseases such as Parkinson's disease, Huntington's disease (HD), and Alzheimer's disease (AD). The purpose of the work is to find a strategy to reach the neurons intracellularly. The goal is to be able to design a biological drug that enters the neuron by investigating different uptake mechanisms. A systematic review of 43 published studies was reviewed, and the results could be obtained. All result presents data from different receptors, cell-penetrating peptides, and adeno-associated viruses (AAV) that were examined. It showed that there are advantages and disadvantages with all the uptake mechanisms. There are risks of side effects for each uptake mechanism, and further studies are required to consider the risk. AAV2 and the neuron-specific receptors lack specific information about their mechanism, but there is a high potential to develop these strategies. Both AVV and the neuron-specific receptors provide specific uptake into tissues.

intracellular target

neuronal uptake

biological drug

receptor mediated uptake

cell-penetrating peptides

Medical and Health Sciences

Medicin och hälsovetenskap

Intracellular Delivery of Functional Cargos Using Cell Penetrating Peptide Motifs

Salim, Heba

January 2021

No description available.

Chemistry

Biochemistry

Intracellular Delivery

Cell penetrating peptides

peptidyl inhibitor

Keap1-Nrf2 Interaction

Ras binding domain

Site-Specific Conjugation

Studium účinku modifikace virových částic polyhistidinem na jejich intracelulární lokalizaci a dopravu genů do jádra / Effect of polyhistidine modification of viral particles on their intracellular localization and gene delivery to the nucleus

Číhařová, Barbora

January 2021

Viral vectors derived from mouse polyomavirus are a convenient tool for studying the targeted delivery of therapeutical agents into the cells and cellular organelles. Vectors derived from mouse polyomavirus face difficulties similar to other nanoparticles, as they often end up trapped inside an endosome where they are subsequently degraded. This diploma explored the potential of vector modifications, which have the potential to make the transport to the nucleus or cytosol more effective. This work had particularly focused on increasing the transduction efficiency by modifying particle's internally localized VP3 capsid protein with covalently bound membrane-penetrating peptides. Primary covalent genetic modification to the VP3 protein was the polyhistidine peptide KH27K. Its potential of improving the transduction effectivity was compared with two other peptide modifications - LAH4 and R8. The results of the transduction test showed that covalently bound R8 peptide had many-fold improved the transport to the nucleus when compared to the unmodified particles. The modification with LAH4 peptide had been regarded more effective only when was associated with the particles non-covalently. In such scenario the transduction efficiency rose 40-times when compared with unmodified particles. Polyhistidine...

Lipid membrane interaction with self-assembling cell-penetrating peptides / Interactions des membranes lipidiques avec des peptides pénétrateurs de cellules auto-assemblants

Walter, Vivien

12 September 2017

Les peptides pénétrateurs de cellule (CPP) sont des oligopeptides cationiques faisant parti des vecteurs les plus étudiés dans le cadre du développement du transport ciblé de médicament à l’intérieur de l’organisme. Les applications principales sont par exemple le traitement des cancers ou la thérapie génique. Néanmoins, certaines caractéristiques des CPPs rendent leur utilisation médicale compliquée, tels que leur manque de spécificité à l’égard des cellules cibles ou la perte de leurs propriétés pénétrantes lorsqu’un cargo moléculaire leur est greffé. L’une des solutions envisagées pour résoudre ces problèmes est le greffage sur des polypeptides di-blocs auto-assemblés basés sur de l’élastine (ELPBC), des systèmes développés par l’équipe d’Ashutosh Chilkoti à l’Université de Duke (USA). Des travaux précédents ont montré que ces macromolécules, que l’on appelle CPP-ELPBC, retrouvaient les propriétés pénétrantes du CPP même en présence d’un cargo et permettaient également d’induire une spécificité à l’encontre des cellules cancéreuses. En revanche, le mécanisme de pénétration de ces systèmes restait inconnu.Dans cette thèse, je me suis concentré sur l’étude du mécanisme de pénétration des CPP et des CPP-ELPBC au travers de membranes lipidiques modèles, et en particulier sur l’adsorption de ces molécules à la surface de vésicules unilamellaires géantes (GUV). Le développement d’une nouvelle méthode de quantification de la fluorescence en microscopie confocale m’a permis de réaliser des mesures simples de comptage de peptides à la surface des vésicules, ce qui m’a permis par la suite de procéder à des mesures thermodynamiques de l’adsorption des peptides. / Cell-penetrating peptides (CPP) are cationic oligopeptides currently investigated as potential vectors for targeted drug delivery design, for applications in cancer treatment and/or gene therapy. Nevertheless, some drawbacks make the CPP complex for medical applications, such as their lack of specificity toward target cells or the loss of their penetrating properties once they have been grafted with a molecular cargo. One of the solutions studied to overcome these issues is the binding of the CPP unit on a self-assembling elastin-like diblock polypeptide (ELPBC), a macromolecular system designed by the team of Ashutosh Chilkoti from Duke University (USA). While it has already been proven that these molecules, named CPP-ELPBC, recover the penetrating properties of the CPP despite the presence of a cargo and also induce a selectivity toward tumorous cells, the exact mechanism of translocation is still under debate.In this PhD thesis, I focused on the investigation of the translocation mechanism of the CPP and CPP-ELPBC using model lipid membranes, and specifically the adsorption of these molecules at the surface of giant unilamellar vesicles (GUV). The development of a new quantification method of fluorescence in confocal microscopy allowed me to directly count the peptides adsorbed on the surface of the GUVs, which I used to perform thermodynamic measurements on the peptide adsorption.

Lipides

Peptides pénétrateurs de cellules

Membranes modèles

Adsorption

Fluorescence

Microscopie confocale

Lipids

Cell-penetrating peptides

Model membranes

Adsorption

Fluorescence

Confocal microscopy

Elastin-like polypeptides

571.4

Desenvolvimento de nanopartículas de fase líquido-cristalina funcionalizadas com peptídeos de penetração celular para carreamento do ácido lipóico na pele / Development of liquid crystalline phase nanoparticles functionalized with cell penetrating peptides for carrying lipoic acid in the skin

Campos, Patrícia Mazureki

04 March 2016

A modulação da penetração de fármacos na/através da pele representa um desafio para sobrepor o efeito barreira proporcionado pela camada mais externa da pele, o estrato córneo. Sistemas de liberação nanoestruturados e funcionalizados representam uma importante estratégia para promover a penetração de fármacos nas camadas mais profundas da pele. O ácido lipóico (AL) é uma molécula com atividade antioxidante e constitui terapia antioxidante tópica para tratamento de estresse oxidativo e inflamação recorrente em patologias cutâneas. A encapsulação de AL em nanodispersões líquido-cristalinas (NDLCs) funcionalizadas com os peptídeos de penetração celular (PPCs), a saber, os peptídeos D4 e TAT, visa promover a liberação de AL em camadas específicas da pele através de uma estratégia inovadora associando tanto as vantagens de um sistema nanoparticulado como a superfície modificada para melhorar a interação com células e tecido-alvos. Nesse trabalho, foram desenvolvidos e validados métodos de cromatografia líquida de alta eficiência com detectores ultravioleta, eletroquímico e espalhamento de luz evaporativo específicos para quantificação do AL em várias faixas de linearidade para as diferentes etapas experimentais. As NDLCs foram preparadas com monooleato de glicerila, ácido oleico, lipopolímeros, peptídeos TAT e D4 em diversas proporções e associações. NDLCs foram caracterizadas por diferentes métodos. A microscopia de luz polarizada e difração de raios X de baixo ângulo identificaram o sistema líquido-cristalino como fase hexagonal reversa. As técnicas de espalhamento dinâmico de luz e análise de rastreamento mostraram nanopartículas na ordem de 200 nm, estreito índice de polidispersividade, portencial zeta negativo e número de partículas por mL na faixa de 1012. A eficiência de encapsulação foi em torno de 79% e a capacidade de carga (drug loading) de AL nas NDLCs atinigiu 15%. A avaliação de comportamento e ação in vitro das NDLCs foi estudada em queratinócitos e fibroblastos, evidenciando que o tratamento com as NDLCs não diminuiu a viabilidade celular nas células estudadas. A internalização celular das NDLCs comprovada por microscopia confocal a laser e citometria de fluxo foi aumentada com a funcionalização com peptídeo D4 de maneira dependente da concentração e do tempo de incubação e com peptídeo TAT por mecanismo inespecífico. Em estudos de permeação in vitro foi demonstrada a penetração cutânea aumentada de AL a partir das NDLCs. Ensaio in vivo com camundongos hairless expostos à radiação UVB evidenciou a eficácia das NDLCs contendo AL pela atividade de mieloperoxidase ter sido diminuída, além de menor liberação da citocina inflamatória TNF-?, mostrando que as NDLCs desenvolvidas podem ser uma opção de tratamento tópico contra processos de estresse oxidativo e inflamação presentes no envelhecimento cutâneo e outras desordens cutâneas. / The modulation of drug penetration into/ through the skin presents a challenge to overcome the barrier effect provided by the outermost layer of skin, the stratum corneum. Nanostructured and functionalized delivery systems represent an important strategy for promoting drugs penetration into the deeper layers of the skin. Lipoic acid (LA) is a molecule with antioxidant activity and it has application in topical antioxidant therapy for the treatments of oxidative stress and cutaneous inflammation pathologies . LA encapsulation into liquid crystalline nanodispersions (LCNDs) functionalized with cell penetrating peptides (CPPs), namely, D4 and TAT peptides, aims to promote LA release in specific layers of the skin through an innovative strategy combining both the advantages of nanoparticulate system with modified particle surface to enhance the interaction with cell and tissue-targets. In this work, we developed and validated high performance liquid chromatography methods with ultraviolet, electrochemical and evaporative light scattering detectors aiming to achieve specificity to assay LA in several linearity ranges for the different experimental stages. The NDLCs were prepared with glyceryl monooleate, oleic acid, lipopolymers, TAT and D4 peptides in various ratios and associations. LCNDs were characterized by several methods. The polarized light microscopy and small angle Xray diffraction identified the liquid crystalline system as reverse hexagonal phase. Techniques of dynamic light scattering and nanotracking analysis showed nanoparticles in the order of 200 nm, narrow polydispersity index, negative zeta potential and number of particles per mL in the range of 1012. The encapsulation efficiency was around 79%, and LA drug loading in LCNDs reached 15%. Assessment of in vitro behavior and effect of LCNDs was studied in keratinocytes and fibroblasts, demonstrating that LCNDs treatment did not decrease cell viability for studied cells. The cell internalization of LCNDs demonstrated by confocal laser microscopy and flow cytometry was increased by functionalization with D4 peptide in concentration and time of incubation dependent manners and with TAT peptide in a nonspecific mechanism. In vitro permeation studies demonstrated the increased skin penetration of LCNDs loaded LA. In vivo assay with hairless mice exposed to UVB radiation evidenced the efficacy of LCNDs loaded LA by myeloperoxidase activity have been reduced, also reduced release of inflammatory cytokine TNF-?, indicating that the developed LCNDs can be an alternative for topical treatment against processes of oxidative stress and inflammation present in skin aging and other skin disorders.

ácido lipóico

aplicação tópica.

cell penetrating peptides

estresse oxidativo

funcionalização

functionalization

lipoic acid

liquid crystalline nanodispersions

nanodispersões líquido-cristalinas

oxidative stress

pele

peptídeos de penetração celular

skin

topical application