Webinar on

Nanomedicine

Scientific Program

Keynote Session:

Meetings International -  Conference Keynote Speaker PROF. SHLOMO MAGDASSI photo

PROF. SHLOMO MAGDASSI

The Hebrew University of Jerusalem, Israel

Title: ADDITIVE MANUFACTURING: THE NEXT INDUSTRIAL REVOLUTION

Biography:

Shlomo Magdassi is a professor at the Institute of Chemistry of The Hebrew University of Jerusalem. He is the Director of the Center for Functional and 3D Printing, and holds the Enrique Berman Chair in solar energy. His research focuses on micro and nanomaterials and their applications in functional inks such as printed electronics, 2D, 3D and 4D printing. He is the author over 300  publications and the editor of 4 books.He also has more than 80 inventions (38 US granted patents, ~300 PCT applications), which are related to applications of dispersed systems in various industries. Based on his inventions, many commercial activities evolved, which led to licensing, worldwide sales and establishing new start-up companies.

Abstract:

Additive manufacturing which is based on printing processes, is considered as the next industrial revolution. Functional printing brings additional performance of printed patterns, beyond the conventional graphic output, and the nmain bottleneck in this field is the lack of suitable materials. The synthesis and formulations of novel nanomaterials and inks will be presented, with their utilization in printed devices, responsive and 3D objects. New approaches for achieving conductive inks for printed plastic electronics will be presented, as well as new materials and processes for 3D and 4D printing. Utilization of 3D and 4D printing technologies for fabrication of objects composed of ceramics, shape memory polymers, elastomers and hydrogels will be demonstrated, for applications such as soft robotics, drug delivery systems, responsive connectors and Internet of Things (IoT),  dynamic jewelry and medical devices.

Meetings International -  Conference Keynote Speaker ASSOC PROF DR. VIKTOR CHIKAN photo

ASSOC PROF DR. VIKTOR CHIKAN

Kansas State University, USA

Title: DRIVING MOLECULAR TRANSPORT ACROSS BIOLOGICAL MEMBRANES FROM MAGNETIC NANOPARTICLE/PULSED MAGNETIC FIELD

Biography:

Associate Professor, Group Leader ELI-ALPS research facility, Sabbatical at the University of Szeged, Dep. of Optics and Quantum Electronics, Assistant Professor, Postdoc, UC, Berkeley and LBNL (advisor: Prof. Stephen R. Leone),PhD, Kansas State University (advisor: Prof. David F. Kelley at UC, Merced now), Bend Research Inc.,M.Sc., University of Szeged

Abstract:

Our research aim is to investigate how magnetic nanoparticles and magnetic field combinations can be used to open up pores on various membranes to facilitate transport of various sized molecules. The research will address the underlying fundamental challenges that limit the efficient use of various types of magnetic fields for creating a biological response such as cell death, change in function. In this research, cell, bacterial and liposomal model systems will be investigated when nanoparticles are integrated into their structure and exposed to various types of magnetic fields such as short homogeneous and inhomogeneous magnetic pulses, linearly and circularly polarized magnetic fields, or small amplitude AC magnetic fields. The transport properties will be evaluated using fluorescence techniques based on permeability essays, electrochemical essays detecting small trace molecules and based on exploring the biological response of the system such as cell viability. Addition characterization techniques will be necessary to accurately survey the structure of these systems prior and post exposure to the magnetic fields. In this research, we will implement spectroscopic and microscopic techniques to explore spatial and dynamical aspects of the magnetic fields on proposed systems. Integration of fluorescence microscopy with electromagnet will allow studying the systems under the I influence of the magnetic fields. Spectroscopic method based on magnetic field transient Faraday rotation of the magnetic particles and dynamical measurements of ultrasonic intensities will explore the transfer of the magnetic field’s energy into mechanical movement in the medium.