Fernanda Belincanta Borghi-Pangoni

Rheological, mucoadhesive and textural properties of thermoresponsive polymer blends for biomedical applications.

The development of binary polymeric mixtures (polymer blends) containing bioadhesive and thermoresponsive polymers can provide new materials for biomedical applications, with higher contact, increased adhesion, prolonged residence time, protection, and in determined cases, secured absorption of an active agent from the site of application. Mixtures were prepared using a wide range of poloxamer 407 and Carbopol 971P(®) amounts. The rheological (flow and oscillatory), sol-gel transition temperature, mechanical (hardness, compressibility, adhesiveness, cohesiveness and elasticity), softness, and mucoadhesive properties of formulations were investigated. Moreover, the interaction between the different proportions of polymers was also analyzed. Continuous shear and oscillatory rheometry identified the plastic flow with various degrees of thixotropy, besides the viscoelastic behavior of formulations. The determination of gelation temperature displayed values ranged from 27.17 to 41.09°C. It was also found that low carbomer concentrations were enough to provide positive interaction parameter. However, the highest values were obtained for the polymeric blends with higher concentration of poloxamer 407. The mucoadhesion and softness index were greater in preparations containing 20% (w/w) poloxamer 407. The rheological, mechanical and mucoadhesive properties of the polymeric blends can be manipulated by changing the concentrations of the polymers and they suggest the blends are worthy of biomedical applications.

Functional Polymeric Systems as Delivery Vehicles for Methylene Blue in Photodynamic Therapy

Antibiotic-resistant microorganisms have become a global concern, and the search for alternative therapies is very important. Photodynamic therapy (PDT) consists of the use of a nontoxic photosensitizer (PS), light, and oxygen. This combination produces reactive oxygen species and singlet oxygen, which can alter cellular structures. Methylene blue (MB) is a substance from the phenothiazine class often used as a PS. In this work, to facilitate the PS contact within the wounds, we have used Design of Experiments 2(3) plus central point to develop functional polymeric systems. The formulations were composed by poloxamer 407 [15.0, 17.5, or 20.0% (w/w)], Carbopol 934P [0.15, 0.20, or 0.25% (w/w)], and MB [0.25, 0.50, or 0.75% (w/w)]. The sol-gel transition temperature, flow rheometry, in vitro MB release, and ex vivo study of MB cutaneous permeation and retention were investigated. Moreover, the evaluation of photodynamic activity was also analyzed by in vitro degradation of tryptophan by singlet oxygen and using Artemia salina. The determination of the gelation temperature displayed values within the range of 25-37 °C, and the systems with better characteristics were subjected to rheological analysis and in vitro release profiling. The 20/0.15/0.25 formulation showed the best release profile (42.57% at 24 h). This system displayed no significant skin permeation (0.38% at 24 h), and the photooxidation of tryptophan test showed the production of reactive species of oxygen. The toxicity test using A. salina revealed that the MB associated with the light increased the mortality rate by 61.29%. Therefore, investigating the PDT efficacy of the functional polymeric system containing MB will be necessary in the future.

Screening and In Vitro Evaluation of Mucoadhesive Thermoresponsive System Containing Methylene Blue for Local Photodynamic Therapy of Colorectal Cancer.

PurposePhotodynamic therapy (PDT) with methylene blue (MB) constitutes a potentially useful modality for colorectal cancer treatment. The limitations of the formulations containing MB are problems of administration and the inability to get the closeness contact at the site during the appropriate residence time. Present study aimed to develop and characterize mucoadhesive thermoresponsive system containing MB designed as platform for colorectal cancer therapy.MethodsFormulations composed of different amounts of poloxamer 407 (Polox), Carbopol 934P (Carb), and MB were developed and characterized as rheological, compressional, mucoadhesive and syringeability properties, toxicity, photodynamic action, in vitro MB release profile, and ex vivo MB intestinal permeation.ResultsThe different compositions resulted in formulations with distinctive macroscopic characteristics and wide range of gelation temperatures. The compressional flow, mucoadhesive, syringeability, and rheological properties were significantly influenced by temperature and/or composition. The MB release from formulation was governed by anomalous transport. In addition, it was observed that MB permeated the intestinal membrane; the formulation possesses photodynamic activity and low toxicity.ConclusionsThe data obtained from the system composed of 20% Polox, 0.15% Carb, and 0.25% MB indicated a potentially functional role in PDT of the colorectal cancer and suggest it is worthy of clinical evaluation.

Evaluation of the methylene blue addition in binary polymeric systems composed by poloxamer 407 and Carbopol 934P using quality by design: rheological, textural, and mucoadhesive analysis

Abstract This study describes the investigation about the physicochemical behavior of methylene blue (Mb) addition to systems containing poloxamer 407 (Polox), Carbopol 934P (Carb), intended to be locally used by photodynamic therapy. A factorial design 23 (plus center point) was used to analyze the rheological, mucoadhesive and textural properties of the preparations. Systems containing the lower concentrations of Polox (15 and 17.5%, w/w) exhibited pseudoplastic flow and low degrees of rheopexy. On the other hand, at higher Polox concentration (20%, w/w) the systems display plastic flow and thixotropy. Carb and Mb exhibited a negative influence for the consistency and flow behavior index, due to the interaction between them. For most of the formulations, the increase of Polox and Mb content significantly increased storage modulus, loss modulus and dynamic viscosity. The systems display a sol–gel transition temperature, existing as a liquid at room temperature and gel at 29–37 °C. Increasing the temperature and the polymer concentration, the compressional properties of systems significantly increased. The mucoadhesion was noted to all formulations, except to systems composed by 15% (w/w) of Polox. The analyses enabled to understand and predict the performance of formulations and the polymer–Mb interactions, tailoring to the suit systems (Polox/Carb/Mb): 17.5/0.50/0.20 and 20/0.15/0.25.

Development and characterization of multiple emulsions for controlled release of Trichilia catigua (Catuaba) extract

Abstract Considering the antioxidant activity of the Trichilia catigua extract (TCE), the aim of the current study was to develop and characterize W/O/W multiple emulsions containing different vegetable oils as a platform to deliver a TCE. The extract displayed antioxidant activity (IC50) of 4.59 µg/mL and total phenol content (TPC) of 50.84%. Formulations were prepared by the phase-inversion emulsification method and analyzed for morphological appearance, pH, conductivity, droplet size and distribution, content of active, rheological properties, in vitro release, skin permeation, and stability. Formulations prepared with canola oil were selected and displayed regular morphology, mean diameter 2.77 µm (without TCE), 3.07 µm with 0.5% and 3.23 µm with 1.0% TCE. Rheometry (flow) showed pseudoplastic behavior with minimal thixotropy for both systems. TCE could be released from emulsions containing 1.0% and 0.5% TCE in a controlled manner for 16 and 23 h, respectively. The emulsions allowed good retention of TCE in the skin (stratum corneum, epidermis, and dermis). In a 180-d assessment of accelerated chemical stability, TPC was more reduced for the emulsions at 40 °C; other parameters remained stable. Multiple emulsions containing TCE were developed, exhibited good characteristics, and may be considered for future investigations as anti-aging formulations for the skin.

Preparation and characterization of bioadhesive system containing hypericin for local photodynamic therapy

Hypericin (Hyp) is a natural photoactive pigment utilized in the treatment of different types of cancer and antimicrobial inactivation using photodynamic therapy (PDT). Hyp is poorly soluble in water leading to problems of administration, getting close contact with the site, and bio-availability. Therefore, this study aimed to develop bioadhesive thermoresponsive system containing Hyp for local PDT. Carbomer 934P, poloxamer 407, and Hyp were used to prepare the thermoresponsive bioadhesive formulations. They were characterized for sol-gel transition temperature, mechanical, mucoadhesive, rheological (continuous flow and oscillatory) and dielectric properties, syringeability, in vitro Hyp release kinetics, ex vivo permeability, and photodynamic activity. The formulations displayed suitable gelation temperature and rheological characteristics. The compressional, mechanical and mucoadhesive properties, as well the syringeability showed the easiness of administration and the permanence of the system adhered to the mucosa or skin. The dielectric analysis helped to understand the Hyp availability, and its release presented an anomalous behavior. The system did not permeate the pig skin nor rat intestine and showed good biological photodynamic activity. Therefore, data obtained from the bioadhesive system indicate a potentially useful role as a platform for local hypericin delivery in PDT, suggesting it is worthy of in vivo evaluation.

The importance of the relationship between mechanical analyses and rheometry of mucoadhesive thermoresponsive polymeric materials for biomedical applications

Pluronic F127® was associated with a carbomer homopolymer type B, as a model polymer blend to evidence the information provided by rheological and mechanical analyses on the development of bioadhesive thermoresponsive systems. The mechanical analysis enabled to observe that 20% (w/w) Pluronic F127®-polymer blends were harder, more adhesive, more mucoadhesive, more compressive and less soft. In addition, continuous flow rheometry demonstrated that the systems were plastic with rheopexy (15%, w/w, Pluronic F127®) or thixotropic (20%, w/w, Pluronic F127®). Oscillatory rheometry exhibited the increase of temperature, and the polymeric concentration increases the elasticity of the formulations. Moreover, correlation index showed that softness and textural analysis can be correlated and complementary, whereas adhesiveness cannot be correlated to mucoadhesion and is less specific. Rheological interaction parameter and gelation temperature showed that 15/0.25-polymer blend is suitable for pharmaceutical and biomedical application, since it can be administered in the liquid form and be gelled in the application site with proper mucoadhesion that can suggest an improved clinical efficacy. Therefore, the mechanical and rheological analyses are useful to characterize and select the best bioadhesive thermoresponsive formulation for the proposed treatment with improved performance.

Investigation of Methylene Blue Release from Functional Polymeric Systems Using Dielectric Analysis

BACKGROUND Methylene blue (MB) is a photosensitizer used in photodynamic therapy (PDT) to treat colorectal cancer tumors and leishmaniasis infection. The clinical efficacy of PDT using MB is dependent on the physicochemical characteristics of the formulation. Bioadhesive thermoresponsive systems containing poloxamer 407 and Carbopol 934P have been proposed as platforms for PDT. However, the effect of MB on the physicochemical properties of these platforms is not fully understood, particularly in light of the MB availability. OBJECTIVE The aim of this study was to investigate the dielectric characteristics of functional polymeric systems containing MB and their influence on mucoadhesion and drug release. METHODS Binary polymeric systems containing different concentrations of poloxamer 407, Carbopol 934P and MB were evaluated as dielectric and mucoadhesive properties, as well as in vitro drug release profile. RESULTS MB, temperature and polymeric composition influenced the physicochemical properties of the systems. The presence of MB altered the supramolecular structure of the preparations. The mucoadhesive properties of systems were influenced by MB presence and the formulation with the lowest amount of MB displayed faster release. CONCLUSION The lower MB concentration in the systems displayed better results in terms of ionic mobility and drug release, and is indicative of a suitable clinical performance.

Environmentally Responsive Systems for Drug Delivery

BACKGROUND In recent decades, the development of the environmentally responsive systems for drug delivery has been well regarded, with enormous potential in different applications. Methods: These environmentally sensitive, smart, intelligent formulations have the ability to alter their physical properties in response to small changes in physical or chemical conditions, such as temperature, glucose, pH, ultrasound, light, electric field and redox potential with a huge potential in drug delivery systems. The use of formulations containing smart materials enables to carry the drug to the target tissue, cells and release in a triggered way. Consequently, they have demonstrated several advantages like decreased dose frequency, ease of preparation and administration, prolonged release with reduced side effects, as well as, reduced costs when compared to conventional processes for industrial applications. In this sense, many patents have deposited, displaying different pharmaceutical devices using responsive systems. Results: There are more than twenty-five patents deposited about thermoresponsive systems. Furthermore, a few number of patents within glucose responsive, ultrasound responsive and light responsive deposited. There also are about eight patents that are pH-responsive, four as electric-field responsive. Most of them cover more than one type of stimuli. Conclusion: Therefore, in this review, since 1975 to 2016, we have categorized, reviewed and discussed the patents, applications, pharmaceutical dosage forms, the importance and perspectives of this environmentally responsive approach as potentially useful therapeutic modality.

Nanostructured therapeutic systems with bioadhesive and thermoresponsive properties

Bioadhesive systems present the ability to get in close contact with the biologic substrate. When the biological surface is the mucosal tissue, the system is called mucoadhesive. Thermoresponsive systems display a significant physicochemical change in response to the temperature modifications. The development of blends composed by bioadhesive thermoresponsive polymers provides new nanostructured therapeutic systems. The Mucoadhesive Thermoresponsive Systems (MTS) can offer easy administration with no irritancy, improve adhesion, which provides increased availability, the contact time, the controlled release, and protection of the active agent, and consequently, major patient adherence to the therapeutics. The MTS are designed to delivery active agents to different mucous, such as buccal, ocular, nasal, vaginal, and colorectal. These polymeric blends can be composed by poloxamer 407 (P407) and carbomers (Carbopol 934P, Carbopol 971P, Carbopol 974P), polycarbophil, chitosan, alginates, guar gum, carrageenan, and polymers derived from cellulose. Therefore, in this chapter, we have assessed and discussed the importance, applications, and perspectives of this novel approach as potentially useful therapeutic modality.