J. M. Lanao

Critical factors in the release of drugs from sustained release hydrophilic matrices

Hydrophilic matrix systems are one of the most interesting drug delivery systems, and they are currently some of the most widely used to control the release rate of drugs. There are too much factors involved in drug release from hydrophilic matrix systems. The most important factors to be taken into account when developing a formulation based on hydrophilic matrices are the percentage, solubility and drug particle size; the type of polymer, the percentage incorporated, its degree of viscosity and the polymer particle size. Also important are the drug/polymer ratio and the amount of water entering the matrix. Other factors have been shown to be involved in the release of drugs, such as the percentage and mixtures of polymers and the dimensions of the matrix. The compression force is important among the formulation factors to the extent that it determines the amount of air trapped in the matrix. Knowledge of these factors involved in the release of the drugs is crucial for the optimal development of formulations based on hydrophilic systems.

Current applications of nanoparticles in infectious diseases.

For decades infections have been treated easily with drugs. However, in the 21st century, they may become lethal again owing to the development of antimicrobial resistance. Pathogens can become resistant by means of different mechanisms, such as increasing the time they spend in the intracellular environment, where drugs are unable to reach therapeutic levels. Moreover, drugs are also subject to certain problems that decrease their efficacy. This requires the use of high doses, and frequent administrations must be implemented, causing adverse side effects or toxicity. The use of nanoparticle systems can help to overcome such problems and increase drug efficacy. Accordingly, there is considerable current interest in their use as antimicrobial agents against different pathogens like bacteria, virus, fungi or parasites, multidrug-resistant strains and biofilms; as targeting vectors towards specific tissues; as vaccines and as theranostic systems. This review begins with an overview of the different types and characteristics of nanoparticles used to deliver drugs to the target, followed by a review of current research and clinical trials addressing the use of nanoparticles within the field of infectious diseases.

High-performance liquid chromatographic validated assay of doxorubicin in rat plasma and tissues

A specific and selective high-performance liquid chromatography (HPLC) technique that requires few manipulations, and is readily adaptable to analysis for a large series of samples, has been developed for the determination of the concentration of the anticancer drug doxorubicin (DXR) in rat serum and tissues. The biological samples were efficiently deproteinised and resolved from a reversed-phase nucleosil C18 column with fluorescence detection. The validation study of the proposed method was successfully carried out in an assay range of between 5 and 5000 ng/ml and was subsequently implemented in a pharmacokinetic study of DXR in Wistar rats that were treated by intravenous administration of the drug.

International seminar on the red blood cells as vehicles for drugs.

The first human transfusion was performed by the pioneer Dr Jean-Baptiste Denis in France in 1667 and now, three centuries later, around 50 millions blood units are transfused every year, saving millions of lives. Today, there is a new application for red blood cells (RBCs) in cellular therapy: the effective use of erythrocytes as vehicles for chemical or biological drugs. Using this approach, the therapeutic index of RBC-entrapped molecules can be significantly improved with increased efficacy and reduced side effects. This cell-based medicinal product can be manufactured at an industrial scale and is now used in the clinic for different therapeutic applications. A seminar dedicated to this field of research, debating on this inventive formulation for drugs, was held in Lyon (France) on 28 January 2011. Drs KC Gunter and Y Godfrin co-chaired the meeting and international experts working on the encapsulation of drugs within erythrocytes met to exchange knowledge on the topic ‘The Red Blood Cells as Vehicles for Drugs’. The meeting was composed of oral presentations providing the latest knowledge and experience on the preclinical and clinical applications of this technology. This Meeting Highlights article presents the most relevant messages given by the speakers and is a joint effort by international experts who share an interest in studying erythrocyte as a drug delivery vehicle. The aim is to provide an overview of the applications, particularly for clinical use, of this innovative formulation. Indeed, due to the intrinsic properties of erythrocytes, their use as a drug carrier is one of the most promising drug delivery systems investigated in recent decades. Of the different methods developed to encapsulate therapeutic agents into RBCs [1,2,] the most widely used method is the lysis of the RBCs under tightly controlled hypotonic conditions in the presence of the drug to be encapsulated, followed by resealing and annealing under normotonic conditions (Figure 1). This results in uniform encapsulation of the material into the cells and a final product with good stability, reproducibility and viability. This process, which has now been developed to an industrial scale, is the technique chosen by the majority of the experts presenting their work in this seminar (by R Franco). Figure 1 The process of reversible hypotonic lysis of RBCs to entrap molecules Keywords: carriers, drug delivery, erythrocytes, red blood cells, targeting 1. Therapeutic enzyme-loaded RBCs Therapy using RBC encapsulated enzymes has the advantage of prolonging the half-life of the enzyme and maintaining therapeutic blood levels, reducing the dosage and frequency of therapeutic interventions, and preventing the need for expensive chemical modification [3]. The therapeutic index can be strongly improved, especially by reducing immunogenic reactions, which are often observed in enzyme replacement (Figure 2). Figure 2 The red blood cell as a bioreactor: the substrate (yellow) contained in the plasma permeates the erythrocyte membrane, with the entrapped enzyme (green) catalyzing the metabolism of the substrate to its normal product inside the red cell 1.1 L-asparaginase-loaded RBCs for ASNS-deficient tumor (by E Dufour) L-asparaginase has been used in the treatment of acute lymphoblastic leukemia for > 40 years. This enzyme converts plasmatic L-asparagine (L-Asn) into L-aspartate plus ammonia. Its use is motivated by the fact that malignant cells (especially leukemic) are deficient in asparagine synthetase (ASNS). Because these cells are unable to synthesize L-Asn to meet metabolic demands, L-Asn deprivation, due to L-asparaginase activity, kills the cancerous cells. However, L-asparaginase can also be responsible for adverse events such as hypersensitivity reactions or blood coagulations disorders, in addition to L-Asn depletion. An approach to decreasing side effects of free L-asparaginase in vivo is to entrap the enzyme in RBCs. Reversible hypotonic dialysis remains the most controlled and reproducible method. Indeed, with this process, human RBCs can be loaded with 116 ± 15 IU of L-asparaginase per milliliter of red cells. The resulting product acts as a bioreactor allowing transport of L-Asn through the RBC membrane where L-asparaginase hydrolyzes it. Due to the RBC membrane, the enzyme is protected from rapid catabolism as well as from potential neutralizing antibodies, resulting in an increased half-life and a reduction in hypersensitivity reactions. A Phase I–II trial testing GRASPA® (ERYTECH Pharma, France) on 24 patients in relapsed acute lymphoblastic leukemia showed a strong reduction in hypersensitive reactions, coagulation disorders and hepatic dysfunctions [4]. The L-asparaginase half-life is enhanced (40 days vs 1 day with the free form) and the mean duration of L-Asn depletion is 18.57 days at a dose of 150 IU/kg in a single injection that corresponds to eight injections of Escherichia coli native L-asparaginase. This improvement in tolerance allows the introduction of L-asparaginase treatment to other hematological malignancies, such as acute myeloid leukemia, and also in solid tumors. Indeed, the level of expression of L-ASNS, the enzyme responsible for the synthesis of L-Asn in mammalian cells, provides a rationale for testing L-asparaginase in several cancers. For example, about 30 and 40% of pancreatic ductal adenocarcinoma patients (85 – 90% of all pancreatic cancer subjects) have no or low level of expression of ASNS, respectively. A Phase I clinical study is ongoing with pancreatic adenocarcinoma patients.

Recent advances in delivery systems for anti-HIV1 therapy

In the last years, different non-biological and biological carrier systems have been developed for anti-HIV1 therapy. Liposomes are excellent potential anti-HIV1 carriers that have been tested with drugs, antisense oligonucleotides, ribozymes and therapeutic genes. Nanoparticles and low-density lipoproteins (LDLs) are cell-specific transporters of drugs against macrophage-specific infections such as HIV1. Through a process of protein transduction, cell-permeable peptides of natural origin or designed artificially allow the delivery of drugs and genetic material inside the cell. Erythrocyte ghosts and bacterial ghosts are a promising delivery system for therapeutic peptides and HIV vaccines. Of interest are the advances made in the field of HIV gene therapy by the use of autologous haematopoietic stem cells and viral vectors for HIV vaccines. Although important milestones have been reached in the development of carrier systems for the treatment of HIV, especially in the field of gene therapy, further clinical trials are required so that the efficiency and safety of these new systems can be guaranteed in HIV patients.

Bayesian forecasting in paediatric populations.

SummaryBayesian forecasting offers several important advantages for dosage individualisation in children, although, unlike for adults, its use in this population is much lower. Indeed, currently Bayesian methods are underused in this patient population. The paucity of paediatric population pharmacokinetic parameters, and the unavailability of specific clinical pharmacokinetic software for the whole paediatric population, are the main limitations to the application of Bayesian methods in these patients. When these problems have been overcome, this approach will allow clinicians to achieve therapeutic concentrations more readily, faster and more precisely, thus making the methodology highly attractive in the paediatric setting.

Drug-loaded erythrocytes: on the road toward marketing approval

Erythrocyte drug encapsulation is one of the most promising therapeutic alternative approaches for the administration of toxic or rapidly cleared drugs. Drug-loaded erythrocytes can operate through one of the three main mechanisms of action: extension of circulation half-life (bioreactor), slow drug release, or specific organ targeting. Although the clinical development of erythrocyte carriers is confronted with regulatory and development process challenges, industrial development is expanding. The manufacture of this type of product can be either centralized or bedside based, and different procedures are employed for the encapsulation of therapeutic agents. The major challenges for successful industrialization include production scalability, process validation, and quality control of the released therapeutic agents. Advantages and drawbacks of the different manufacturing processes as well as success key points of clinical development are discussed. Several entrapment technologies based on osmotic methods have been industrialized. Companies have already achieved many of the critical clinical stages, thus providing the opportunity in the future to cover a wide range of diseases for which effective therapies are not currently available.

Encapsulation and in vitro evaluation of amikacin-loaded erythrocytes.

The aim of our present work was to establish the effect of the osmolality of the hypotonic buffer on the encapsulated amount and the in vitro properties of Amikacin-loaded erythrocytes. Amikacin was encapsulated in rat erythrocytes using a hypotonic dialysis method with hypotonic buffers of different osmolalities with mean values around 90 and 150 mOsm/kg. Morphological examination of the ghost erythrocytes was accomplished using scanning electron microscopy (SEM). The osmotic fragility of normal and loaded erythrocytes was tested using hypotonic solutions. Evaluation of the hematological parameters of the control and loaded erythrocytes was carried out using a hematology system analyzer. Amikacin release from loaded erythrocytes was tested in autologous plasma at 37°C over a 24-h period. The quantification of Amikacin in loaded erythrocytes and in autologous plasma was performed using an HPLC technique. A higher osmotic fragility of loaded erythrocytes was observed using a low osmolality buffer. Some hematological parameters showed statistically significant differences between the loaded erythrocytes obtained using two buffers of different osmolalities with respect to untreated erythrocytes. According to our results, Amikacin carrier erythrocytes obtained by hypotonic dialysis using a low osmolality buffer (90 mOsm/kg) should afford a good encapsulation yield, appropriate morphological properties, and sustained release in vitro.

In vitro studies of amikacin-loaded human carrier erythrocytes

Erythrocyte-encapsulated antibiotics have the potential to provide an effective therapy against intracellular pathogens. The advantages over the administration of free antibiotics include a lower systemic dose, decreased toxicity, a sustained delivery of the antibiotic at higher concentrations to the intracellular site of pathogen replication, and increased efficacy. In this study, the encapsulation of amikacin by human carrier erythrocytes prepared using a hypo-osmotic dialysis was investigated. The effects of the initial amikacin dialysis concentration and hypo-osmotic dialysis time on the encapsulation efficiency of amikacin were determined, and the osmotic fragility and hematologic parameters of amikacin-loaded carrier erythrocytes were measured. The efficiency of amikacin entrapment by carrier erythrocytes was dependent on the initial dialysis concentration of the drug. Statistically significant differences in the osmotic fragility profiles between control and carrier erythrocytes were observed, which were dependent on the hypo-osmotic dialysis time and on the dialysis concentration of amikacin. Mean hematologic parameters were evaluated and compared with unloaded, native erythrocytes; the mean corpuscular volume (MCV) of amikacin-loaded carrier erythrocytes was statistically significant smaller. Amikacin demonstrated a sustained release from loaded erythrocytes over a 48-h period, which suggests a potential use of the erythrocyte as a slow systemic-release system for antibiotics.

Time-dependent pharmacokinetics of cyclosporine (Neoral) in de novo renal transplant patients.

Purpose:  A model for the large scale temporal trend in the oral bioavailability of microemulsion cyclosporine (Neoral®) (CsA) is established, with dependence on post‐(renal) transplantation day (PTD).