23^rd International Conference on Pharmaceutical Biotechnology December 10-11, 2018 Rome, Italy

Biography:

Abstract:

Biography:

Rodríguez-López L is a PhD student at the University of Vigo. She has completed her Master’s degree in Advanced Biotechnology in 2016, at University of Vigo. She has co-authored six articles in JCR journals. Moreover, she has collaborated for three months in the Department of Pharmacy at University of Huddersfield, United Kingdom.

Abstract:

Statement of the Problem: Biosurfactants are amphiphilic compounds with surface properties produced by microorganisms or obtained from biological cells. They have not only the same applications than their synthetic counterparts but also better characteristics in terms of biocompatibility and biodegradation. Although they have been proved in different areas such as bioremediation, their uses are increasing in food and cosmetic formulations. In these areas, microbiology properties are one of the most important parameter to control, so it is necessary to evaluate biosurfactants behavior in presence of microorganisms.
Methodology: Two biosurfactant extracts were produced following the methodologies established by Vecino et al. one obtained from corn steep liquor (CSL) and the other from Lactobacillus pentosus. Both biosurfactants were diluted up to 1 g/L of and put in contact with a known concentration of pathogenic microorganisms including Candida albicans, Aspergillus brasiliensis and Pseudomonas aeruginosa, at 22.5 ºC. The effect of these biosurfactants on the microorganism growth was evaluated each 7 days during a month. The culture conditions for obtaining the inoculum of each microorganism were reflected.
Findings: The experiment carried out with biosurfactant from CSL, showed antimicrobial activity against P. aeruginosa and A. brasiliensis, thus the concentration of microorganisms was reduced from 2*10⁶ and 2*10⁴ UFC/mL, to 1 and 4*10³ UFC/mL, respectively. In the case of C. albicans, the amount of colonies slightly increased from 2*10⁴ to 8*10⁴ UFC/mL. For the biosurfactant from L. pentosus, the behavior observed was completely different, thus the number of colonies did not change significantly in any of the pathogens tested.
Conclusion & Significance: These results have demonstrated interesting effects of biosurfactant extract from CSL against pathogenic microorganisms, what is in concordance to its antioxidant properties. Furthermore, the biosurfactant from L. pentosus showed lower antimicrobial activity.

Biography:

Myriam Rincón Fontán is a PhD student at the University of Vigo. She has completed her Chemical Engineering Degree at University of Santiago de Compostela in 2014. During the last year of the degree, she has carried out her Master Thesis at the Royal Institute of Technology (KTH) in Stockholm, Sweden in the Department of Biochemistry. In 2015, she has completed her Master degree in Chemical Industry and Research at the University of Vigo in the Physical Chemistry Department.

Abstract:

Biography:

Hanneke Later-Nijland is an Attorney-at-law at Axon Lawyers, Amsterdam, Netherlands. Moreover, she has been trained as a Pharmacist. Furthermore, she has completed her PhD in Clinical Pharmacokinetics and is a former Inspector for Clinical Trials and Pharmacovigilance at the Netherlands Inspectorate for Healthcare, IGZ. She specializes in European and national legal and regulatory issues relating to medicinal products. In her practice, she advises life sciences and healthcare clients and litigates on a wide range of issues, often with a regulatory focus. Her areas of expertise in the medicinal products field covers marketing authorizations, reimbursement, compliance, pharmacovigilance and advertising issues. In addition, she also assists clients with product liability issues and IP and regulatory issues in transactions in the life sciences sector. Furthermore, she is a Lecturer at Leiden University Medical Centre. She regularly publishes on new European legislation and the impact of recent judgments in the sector.

Abstract:

Of late, the cost of medicines is a recurring subject of debate in Europe and it is anticipated that this topic will be discussed more intensely in the years to come. In this regard, the application of compulsory patent licensing and the (wider) application of the compounding exemption (formula magistralis) are seriously investigated by the Dutch Minister of Medical Care as an instrument to curb the cost of medicines. In respect to the latter, a legislative proposal is underway which would exonerate pharmacists from patent infringement when compounding medicinal products for direct use for individual cases on medical prescription in pharmacies. This presentation explores in view of the applicable legislation and case law whether these solutions have been correctly identified as the solution to the problem of expensive medicinal products. Pursuant to e.g. the TRIPS Agreement, compulsory patent licensing in view of the general interest is (at least) to be used in combination with an adequate remuneration. Nevertheless, it is worthwhile mentioning that a compulsory license in the public interest was recently granted (and upheld in appeal) in Germany for the HIV drug Isentress. The available case law with respect to compounding and the rationale thereof has demonstrated that it is solely to be utilized as an exception to the rule, which makes it unsuitable as a general solution. Patients are not guaranteed for the same quality control as authorized medicinal products and therefore a proper substantiated justification for this deviation is required. Such justification may when comparing European case law probably not be sought in financial gain leaving aside the fact that this affects the level playing field. This presentation is very relevant for parties manufacturing or marketing high-cost medicinal products.

Biography:

Dinah Weissmann is an Executive Vice President at ALCEDIAG’s, biotech company dedicated to the development of innovative diagnostics based on epigenetic biomarkers mainly RNA editing. She is also Co-director of a public private laboratory, Sys2Diag that was created in 2015 and dedicated to the understanding of molecular basis of complex diseases. Her research fields are mainly in neuroscience which leads to the discovery of a specific plasticity in adult brain coined phenotype plasticity that gave rise to a novel class of antidepressant drugs. Later on, she focused on epigenetic mechanism understanding and developed new tests for diagnosis and management of psychiatric patients as well as prediction of psychiatric adverse effects. She has 15 years of research experience as Director of Research at the CNRS (French academic research institute) and has worked at various leader positions in pharma and biotech companies.

Abstract:

Major depressive and bipolar disorders are leading causes of disability worldwide yet, many people remain undiagnosed or misdiagnosed or ineffectively treated. Diagnosis relies on the clinical assessment of symptoms and currently, there is no molecular diagnostic test available. Identifying and validating blood biomarkers could provide a more accurate and objective means of diagnosis. Genetic and epigenetic events are involved in psychiatric aetiology, among them RNA editing modifications have been associated with inflammation and neuropsychiatric disorders. Adenosine to inosine RNA editing constitutes a physiological cellular process that translates environmental cues by regulating protein function at the synaptic level in health and disease. RNA editing is post-transcriptional process that leads to functional diversity of proteins. These marks form the molecular interface between the genome and the environment. Of particular interest is the RNA editing modification that occurs on the phosphodiesterase 8A gene located on chromosome 15q25.3, a genomic region that has recurrently been associated with early onset of major depressive disorder. ALCEDIAG’s test, EDITDIAG, identifies in blood specific signatures through the RNA editing modifications of patients in different pathological conditions such as a cohort of hepatitis C infected patients, treated with interferon alpha and ribavirin were followed during 16 weeks. This treatment is well known to trigger depression in 50% of patients. RNA editing modifications were measured each two weeks as well as clinical evaluations of depression (MINI). An algorithm was identified which allows to discriminate patients with depression from others with a high specificity and sensitivity; a cohort of depressed patients (n=163) was compared to controls (n=69). A specific RNA editing signature was identified in depressed patients. The test shows that RNA editing related blood biomarkers allow to stratify patients, characterizes psychiatric conditions and follows up the disease/treatment modifications along time. This test paves the way for a better management of psychiatric patients.

Biography:

Kyo-Seon Kim is a Professor of Chemical Engineering at Kangwon National University, Chuncheon, South Korea, where he has been working since 1989. He has completed his BS, MS and PhD degrees in Chemical Engineering at Seoul National University, KAIST and University of Cincinnati, OH, USA in 1979, 1981 and 1989, respectively. His research interests are mainly focused on preparation and modification of nanoparticles for high-functional performances. The main applications of nanoparticles in his researches are in the fields of air pollution control, energy harvesting and development of medical devices.

Abstract:

Recently, studies on therapeutic applications of the magnetic nanoparticles have gained more momentum. The porous/hollow structure also exhibited a great potential to encapsulate small drug molecules. Once inside the porous structures, small drug molecules would be shielded by the shell from fast reaction/deterioration in biological solutions. In our research, monodisperse magnetite Fe₃O₄ porous/hollow nanoparticles were successfully synthesized through one-pot solvothermal process without any surfactant and template as shown in Figure 1. The Fe₃O₄ porous/hollow nanoparticles consisted of numerous tiny grains. Those particles were ferromagnetic with high saturation magnetization. The Fe₃O₄ porous/hollow nanoparticles were synthesized controllably with tunable particle size and porosity by adjusting the initial concentrations of Fe precursor and ammonium acetate. The formation mechanism of the magnetite hollow spheres comprised simultaneous chemical and physical processes including the formation of numerous tiny grains, the spherical assembly of those grains and the chemical conversion coupled with the relocation of the grains. The chemical conversion including a partially reductive reaction of the Fe (III) compounds and subsequent hydrolysis and dehydrolysis reactions of the Fe (III) and Fe (II) compounds to generate Fe₃O₄ caused the non-uniformities of tiny grains and the empty spaces within the spherical assemblies and thus enhanced the outward migration and relocation of the core grains toward the outer layer, resulting in the formation and expansion of the hollow core structure. The porous/hollow nanoparticles could be further coupled with a specific targeting agent and be concentrated around the area of interest, where drug molecules would be released either chemically via a pH control or physically through a magnetic stimulation and activation. Such a controlled drug release warranted the multifunctional porous/hollow nanoparticles a new class of carriers for simultaneous diagnostic and therapeutic applications.

Biography:

Aliona Špakova is a PhD student at Life Sciences Center, Institute of Biotechnology-Vilnius University. Her research aims at generation of novel bacteriophage tail tube originated yeast expressed nanotubes as novel epitope presenting platforms

Abstract:

Statement of the Problem: Current vaccines against infectious diseases have primarily relied on attenuated or inactivated pathogens. However, virus like particles (VLP) are used as vaccine platforms which are more favorable for their perfect defined structures; induction of strong immune response and also suitable for surface decoration by inserted foreign epitopes. While many icosahedral VLPs are synthesized in bacteria and the disadvantages such as lack of post-translational modifications are needed for eukaryotic proteins and contamination of purified VLPs with bacterial endotoxins are encountered. While icosahedral VLP platforms have been studied in detail but rod-shaped VLPs have been mostly forgotten. Until now, there is no information regarding the generation of tailed bacteriophage nanotubes in yeast.
Aim: The research aims to generate nanotubes using yeast expressed bacteriophage tail proteins and determine their tolerance for genetic introduction of foreign epitopes.
Methodology: DNA sequences coding tail proteins of bacteriophages NBD2, FV3 as well as RaK2 were cloned into yeast protein expression vectors. Synthesis of phage proteins was confirmed by protein electrophoresis and rod-shaped structures were analyzed by electron microscopy.
Findings: Our work has focused on developing an alternative epitope presenting rod-shaped platform which could be used for biomedical applications. To our knowledge, it is the first attempt to produce bacteriophage originated nanotubes in yeast cells which determines their tolerance for genetically incorporated foreign epitopes. Yeast protein synthesis system allowed efficient generation of long and flexible nanotubes originated from NBD2 tailed bacteriophage as well as tubes with different morphology from RaK2 and FV3 phages.
Conclusion & Significance: This work intends to show the suitability of yeast protein synthesis system to generate high yields of nanotubes that originate from tailed bacteriophages. The novel strategy presented here could provide safer vaccine candidates compared to the VLPs synthesized in bacteria.