Nanostructured systems of thymol for dermatological and topical treatments

• Autores: Camila Folle
• Directores de la Tesis: Ana C. Calpena Campmany (dir. tes.), Maria Luisa Garcia López (codir. tes.)
• Lectura: En la Universitat de Barcelona ( España ) en 2021
• Idioma: inglés
• Tribunal Calificador de la Tesis: Lyda Halbaut Bellowa (presid.), Paulina Andrea Carvajal Vídal (secret.), Franziska Püschel (voc.)
• Programa de doctorado: Programa de Doctorado en Nanociencias por la Universidad de Barcelona
• Materias:
  • Ciencias médicas
    • Farmacología
      • Análisis de medicamentos
      • Evaluación de medicamentos
      • Medicamentos naturales
      • Fitofármacos
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• Resumen

  • The skin is major organ of the human body, and its function is to protect the internal tissue from environmental changes, maintains the body temperature and avoid penetration of contaminants.

    Therefore, the skin barrier is highly impermeant and it the major challenge for most of compound to be administered dermally. Moreover, the skin possesses resident microbiota, which perform several roles in the skin functionality, more specifically, maintain the sebum levels, the acid pH and protect the skin against other pathogenic microorganism. The healthy skin is a result of an equilibrium of resident microbiota. Their unbalanced proliferation may lead to skin disorders such as infection and inflammation, either caused by internal disfunction or external contaminants. Antimicrobial actives from natural source, such as plant material, are a promoting approach for the treatment of skin infection, should be considered to avoid antibiotic class of drug, which along the treatment normally lead to microbial resistance.

    Natural products are the most favourable active types, since they may not develop side effects, and in the case of antimicrobial agents, they are unlikely to lead to microbial resistance, as most of the antibiotic class of drugs. Plant material are suitable choices, due to their high content of antioxidant compounds, which most of them are phenolic aromatic molecules, which normally possess antimicrobial and anti-inflammatory activities, the key treatment requirement for skin infections.

    Thymol (TH), is a multifunctional monoterpene of aromatic phenolic structure, found naturally occurring in plant extracts or on its white crystalline synthetic form. The effects of TH are largely attributed to its antioxidant properties, via free radical scavenging thus enhancing endogenous antioxidant activities and chelation of metal ions.

    Nanostructured systems, such as polymeric and lipid nanoparticles, may contribute as a novelty approach for management of skin diseases. Nanotechnology offers several advantages to improve active compounds bioavailability after topical administration, since small particle diameters tend to penetrate the deep skin, withdraw the drug in a controlled manner and be mainly retained in the deeper layers.

    Moreover, they constitute an excellent potential candidate in skin disorders, especially for acne treatment, due to their ability to penetrate inside the follicle and provide for long-term release of actives inside the lesions.

    According to the above, the main objective of this work was the development and characterization of polymeric and lipid nanostructured systems containing TH for the treatment of skin infections, mainly focused to the acne. The study consisted of varied surface composition of the nanosystem, in other to enhance the therapeutic efficacy of this novel approach.

    Polymeric and lipid nanoparticles of thymol provided suitable physicochemical morphometry, sustained release, and slow-rate penetration of TH into the hair follicle, being highly retained inside the skin. The therapeutical efficacy was achieved with good results as antimicrobial activity against Cutibacterium acnes and minor effect towards Staphylococcus epidermis, the major resident of the healthy skin microbiota. Moreover, the development of surface-modified polymeric NPs with thymol performed enhanced in vitro anti-inflammatory, antioxidant, and wound healing activities in human keratinocyte cells (HaCaT). Moreover, semi-solid formulations with the nanosystem incorporated had proven to diminish the trans-epidermal water loss due to the film-forming developed on the skin surface.

    Sebum reduction activity was also recorded in oily skin, presenting outstanding results.

    To conclude, nanostructured systems of thymol provided good antimicrobial activity for acne treatment without affecting the healthy skin microbiota. The surface-modification of TH-NPs had proven to be suitable to be used as anti-inflammatory, antioxidant, and wound healing agents, constituting a promising therapy for treating acne infection and associated inflammation. According to the results obtained, the nanostructured systems of thymol and the semi-solid formulations which they were incorporated, demonstrated an outstanding strategy for skin disorders, being considered a novelty approach as a natural treatment of acne. These formulations could be useful for daily application as a complement with other cosmetic and personal hygiene products, for prevention or treatment of also other microbial skin infections.