Fernanda Andrade

Establishment of a triple co-culture in vitro cell models to study intestinal absorption of peptide drugs

In vitro cell culture models for studying oral drug absorption during early stages of drug development have become a useful tool in drug discovery and development, with respect to substance throughput and reproducibility. The aim of this study was to establish an in vitro cellular model based on human colon carcinoma Caco-2, mucus-producing HT29, and Raji B cells in order to design a model that more accurately mimics the small intestinal epithelial layer. Normal oriented model was set up by seeding co-cultures of Caco-2 and HT29 cells into Transwell filters and maintained under identical conditions following addition of Raji B to the basolateral chamber. Inverted model was set up seeding Caco-2 and HT29 cells on the basolateral chamber and then transferred in the Transwell device with the epithelial cells facing the basolateral chamber following Raji B addition to the apical compartment. Morphological differences on size and thickness of cell membranes were detected between the models studied by using fluorescence microscopy. On the triple co-culture models, cell membranes were increasing in size and thickness from the Caco-2 to Caco-2/HT29 and Caco-2/Raji B. Also, the nuclei seem to be larger than in the other studied models. Insulin permeation was higher on the triple co-culture model when compared to the Caco-2/HT29 co-culture model. Also, insulin permeation as mediated by nanoparticles and insulin solution permeation was higher on the normal oriented Caco-2/HT29/Raji B model as compared to the inverted model. Overall, our results suggest that Caco-2/HT29/Raji B triple co-culture normal oriented cellular model may be reliable to obtain a more physiological, functional, and reproducible in vitro model of the intestinal barrier to study protein absorption, both in solution and when delivered by nanocarriers.

Nanotechnology and pulmonary delivery to overcome resistance in infectious diseases

Abstract Used since ancient times especially for the local treatment of pulmonary diseases, lungs and airways are a versatile target route for the administration of both local and systemic drugs. Despite the existence of different platforms and devices for the pulmonary administration of drugs, only a few formulations are marketed, partly due to physiological and technological limitations. Respiratory infections represent a significant burden to health systems worldwide mainly due to intrahospital infections that more easily affect immune-compromised patients. Moreover, tuberculosis (TB) is an endemic infectious disease in many developing nations and it has resurged in the developed world associated with the human immunodeficiency virus/acquired immunodeficiency syndrome (HIV/AIDS) epidemic. Currently, medicine faces the specter of antibiotic resistance. Besides the development of new anti-infectious drugs, the development of innovative and more efficient delivery systems for drugs that went off patent appears as a promising strategy pursued by the pharmaceutical industry to improve the therapeutic outcomes and to prolong the utilities of their intellectual property portfolio. In this context, nanotechnology-based drug delivery systems (nano-DDS) emerged as a promising approach to circumvent the limitations of conventional formulations and to treat drug resistance, opening the hypothesis for new developments in this area.

Cell-based in vitro models for predicting drug permeability

Introduction: In vitro cell models have been used to predict drug permeation in early stages of drug development, since they represent an easy and reproducible method, allowing the tracking of drug absorption rate and mechanism, with an advantageous cost–benefit ratio. Such cell-based models are mainly composed of immortalized cells with an intrinsic ability to grow in a monolayer when seeded in permeable supports, maintaining their physiologic characteristics regarding epithelium cell physiology and functionality. Areas covered: This review summarizes the most important intestinal, pulmonary, nasal, vaginal, rectal, ocular and skin cell-based in vitro models for predicting the permeability of drugs. Moreover, the similitude between in vitro cell models and in vivo conditions are discussed, providing evidence that each model may provisionally resemble different drug absorption route. Expert opinion: Despite the widespread use of in vitro cell models for drug permeability and absorption evaluation purposes, a detailed study on the properties of these models and their in vitro–in vivo correlation compared with human data are required to further use in order to consider a future drug discovery optimization and clinical development.

Nanocarriers for pulmonary administration of peptides and therapeutic proteins

Peptides and therapeutic proteins have been the target of intense research and development in recent years by the pharmaceutical and biotechnology industry. Preferably, they are administered through the parenteral route, which is associated with reduced patient compliance. Formulations for noninvasive administration of peptides and therapeutic proteins are currently being developed. Among them, inhalation appears as a promising alternative for the administration of such products. Several formulations for pulmonary delivery are in various stages of development. Despite positive results, conventional formulations have some limitations such as reduced bioavailability and side effects. Nanocarriers may be an alternative way to overcome the problems of conventional formulations. Some nanocarrier-based formulations of peptides and therapeutic proteins are currently under development. The results obtained are promising, revealing the usefulness of these systems in the delivery of such drugs.

Chitosan-Coated Solid Lipid Nanoparticles for Insulin Delivery

The delivery of therapeutic proteins like insulin, exploiting routes of administration different from the traditional injectable forms, has been investigated extensively, taking advantage of the nanotechnology tools available nowadays in the massive drug delivery system pipeline. In this chapter, we describe in detail the preparation of solid lipid nanoparticles (SLN), further coated with the mucoadhesive polymer chitosan, intended for intestinal absorption of insulin after oral administration. We give special focus on the characterization of the SLN and of the biomacromolecule by itself after encapsulation, because of the intrinsic labile properties of insulin during the manufacturing process. We also describe methods to determine the in vitro intestinal permeability of insulin that solid lipid and chitosan-coated SLN can afford, as well as in vivo models to evaluate the hypoglycemic effect in diabetic animals.

In Vitro and Ex Vivo Evaluation of Polymeric Nanoparticles for Vaginal and Rectal Delivery of the Anti-HIV Drug Dapivirine

Prevention strategies such as the development of microbicides are thought to be valuable in the fight against HIV/AIDS. Despite recent achievements, there is still a long road ahead in the field, particularly at the level of drug formulation. Drug nanocarriers based on polymers may be useful in enhancing local drug delivery while limiting systemic exposure. We prepared differently surface-engineered poly(ε-caprolactone) (PCL) nanoparticles (NPs) and tested their ability to modulate the permeability and retention of dapivirine in cell monolayers and pig vaginal and rectal mucosa. NPs coated with poly(ethylene oxide) (PEO) were shown able to reduce permeability across monolayers/tissues, while modification of nanosystems with cetyl trimethylammonium bromide (CTAB) enhanced transport. In the case of coating NPs with sodium lauryl sulfate (SLS), dapivirine permeability was unchanged. All NPs increased monolayer/tissue drug retention as compared to unformulated dapivirine. This fact was associated, at least partially, to the ability of NPs to be taken up by cells or penetrate mucosal tissue. Cell and tissue toxicity was also affected differently by NPs: PEO modification decreased the in vitro (but not ex vivo) toxicity of dapivirine, while higher toxicity was generally observed for NPs coated with SLS or CTAB. Overall, presented results support that PCL nanoparticles are capable of modulating drug permeability and retention in cell monolayers and mucosal tissues relevant for vaginal and rectal delivery of microbicides. In particular, PEO-modified dapivirine-loaded PCL NPs may be advantageous in increasing drug residence at epithelial cell lines/mucosal tissues, which may potentially increase the efficacy of microbicide drugs.

Models to predict intestinal absorption of therapeutic peptides and proteins.

Prediction of human intestinal absorption is a major goal in the design, optimization, and selection of drugs intended for oral delivery, in particular proteins, which possess intrinsic poor transport across intestinal epithelium. There are various techniques currently employed to evaluate the extension of protein absorption in the different phases of drug discovery and development. Screening protocols to evaluate protein absorption include a range of preclinical methodologies like in silico, in vitro, in situ, ex vivo and in vivo. It is the careful and critical use of these techniques that can help to identify drug candidates, which most probably will be well absorbed from the human intestinal tract. It is well recognized that the human intestinal permeability cannot be accurately predicted based on a single preclinical method. However, the present social and scientific concerns about the animal well care as well as the pharmaceutical industries need for rapid, cheap and reliable models predicting bioavailability give reasons for using methods providing an appropriate correlation between results of in vivo and in vitro drug absorption. The aim of this review is to describe and compare in silico, in vitro, in situ, ex vivo and in vivo methods used to predict human intestinal absorption, giving a special attention to the intestinal absorption of therapeutic peptides and proteins.

Chitosan Formulations as Carriers for Therapeutic Proteins

Protein drugs represent a significant part of the new pharmaceuticals coming on the market every year and are now widely spread in therapy to treat or relief symptomatology related to many metabolic and oncologic diseases. The delivery of therapeutic proteins is still a major drawback against their maximum pharmacodynamic due to their physicochemical properties, poor stability, permeability and biodistribution. Despite the fact that the parenteral route remains the primary route of protein administration, research continues on non-parenteral delivery routes. However, the high molecular weight of proteins, combined with their hydrophilic and charged nature, renders transport through membranes very difficult. In this regard, the biopolymer chitosan exhibits several favorable biological properties, such as biocompatibility, biodegradability, low-toxicity and mucoadhesiveness, which made it a promising candidate for the formulation of protein drugs. The success of a protein formulation depends not only on the stability of the delivery system but also on their ability to maintain the native structure and activity of the protein during preparation and the delivery, as well as during long-term storage of the formulation. Chitosan-based delivery systems have been proposed as valid approaches to provide such protective conditions. The development of novel protein delivery systems based on chitosan is a rising subject irrespective of the intended route of administration. In this review, the different approaches recently exploited to formulate and deliver therapeutic proteins are underlined.

Lipid-based nanovesicles for nanomedicine

Molecular self-assembly has enabled the fabrication of biologically inspired, advanced nanostructures as lipid-based nanovesicles (L-NVs). The oldest L-NVs, liposomes, have been widely proposed as potential candidates for drug delivery, diagnostic and/or theranostic applications and some liposome-based drug products have already stepped from the lab-bench to the market. This success is attributed to their ability to encapsulate both hydrophobic and/or hydrophilic molecules, efficiently carry and protect them within the body and finally deliver them at the target site. These positive features are also coupled with high biocompatibility. However, liposomes still present some unsolved drawbacks, such as poor colloidal stability, short shelf-life, restricted and expensive conditions of preparation because of the inherent nature of their fundamental constituents (phospholipids). The new tools available in the self-assembly of controlled molecules have significantly advanced the field of L-NV design and synthesis, and non-liposomal L-NVs have been recently developed; this new generation of nanovesicles can represent a paradigm shift in nanomedicine: they may complement liposomes, showing their advantages and overcoming most of their drawbacks. Clearly, being still young, their rocky way to the clinic first and then to the market has just started and it is still long, but they have all the potentialities to reach their objective target. The purpose of this review is to first present the large plethora of L-NVs available, focusing on this new generation of non-liposomal L-NVs and showing their similarities and differences with respect to their ancestors (liposomes). Since the overspread of a nanomaterial to the market is also strongly dependent on the availability of technological-scale preparation methods, we will also extensively review the current approaches exploited for L-NV production. The most cutting-edge approaches based on compressed fluid (CF) technologies will be highlighted here since they show the potential to represent a game-change in the production of L-NVs, favouring their step from the bench to the market. Finally, we will briefly discuss L-NV applications in nanomedicine, looking also for their future perspectives.

Chitosan-Grafted Copolymers and Chitosan-Ligand Conjugates as Matrices for Pulmonary Drug Delivery

Recently, much attention has been given to pulmonary drug delivery by means of nanosized systems to treat both local and systemic diseases. Among the different materials used for the production of nanocarriers, chitosan enjoys high popularity due to its inherent characteristics such as biocompatibility, biodegradability, and mucoadhesion, among others. Through the modification of chitosan chemical structure, either by the addition of new chemical groups or by the functionalization with ligands, it is possible to obtain derivatives with advantageous and specific characteristics for pulmonary administration. In this paper, we discuss the advantages of using chitosan for nanotechnology-based pulmonary delivery of drugs and summarize the most recent and promising modifications performed to the chitosan molecule in order to improve its characteristics.