Is “Silicate Life” Possible? -- Nanocarbon Technologies: Prospects and Risks -- Advanced Environment Friendly Nanotechnologies -- Novel Environment Friendly Method of Preparing Nanoreinforced Composites Based on Metallic, Ceramic and Polymer Matrixes – Superdeep Penetration -- Sdp Technology for “Green” Technology of Metallic Reinforced Nanocomposites -- Substantiation of International Nanomaterials Security Group Creation -- Matter Structuring in Nano Scales and Fundamental Constants of Physics -- Size Evolution of Nanoclusters: Comparison Between the Phase Diagram and Properties of MO–S and Carbon Nanoparticles -- Nanomaterials Nexus in Environmental, Human Health, and Sustainability -- Nanotechnology and Quasicrystals: From Self-Assembly to Photonic Applications -- Oscillations of Polarized Charge in Solution of Salt in Polar Dielectric: Possible Application in Element and Isotope Separation in Biology and Nanotechnology -- On the Possible Influence of Resonance Conversion on Formation of the Organic Structures -- Field Driven Current in Nonlinear Low-Dimensional Nanosystems -- The Impact of Novel Technologies on the Environment Throughout History -- Nanotechnoscience as a Cluster of the Different Natural and Engineering Theories and Nanoethics -- Risk in Decision-Oriented and Self-Changing Society -- Technology-Induced Risks in History -- Nanotechnology: Perspective for Future and Nanorisks -- Evaluation of Sustainability of the Carbon and Silicon Ecosystem: From Nanoparticles to Macroworld -- Carbon Discs and Carbon Cones — New High Risk Materials for Nano-Sensors With Low Detection Limit and Fast Kinetics -- Biodynsensing: Sensing Through Dynamics of Hybrid Affinity/Cellular Platforms; Towards Appraisal of Environmental and Biological Risks of Nanobiotechnology -- Synthesis and Utilization of Hyperbranched Poly(Amino Acids) as Carriers of Biologically Active Substances: Problems and Solutions -- Biodegradable and Biocompatible Carbon-Chain Polymer–Protein Conjugates as Carriers of Biologically Active Substances: Problems of Synthesis, Risks of Application and How to Overcome Them -- Modern Risks of Anthropogenic Influence on Living Species: Nano-Level Fluctuation -- Application of Fulleroid Nano-Carbon In Sorption Techniques -- Aspects of Microparticle Utilization for Potentiation of Novel Vaccines: Promises and Risks.

Even though there is no generally accepted definition of nanotechnologies to be defined as distinct discipline there is an emerging consensus that their advent and development is a growing in importance factor of the contemporary and future technological civilization. One of these most fundamental issues we are confronted with is the compatibility with life itself. From single cell organisms to humans, carbon is a key building block of all molecular structures of life. In contrast the man created electronic industry to build on other elements, of which silicon is the most common. Both carbon and silicon create molecular chains, although different in their internal structure. All life is built from carbon-based chains. As long as the man built technological products do not directly interfere with the physiology of life the associated risks from them are relatively easy to identify. They are primarily in the environmental pollution and the possibility of upsetting the natural balance of biocoenosis, on a planetary scale. The basic life functions are still not directly subverted. We can use TV, computers, drive cars and use other technological utilities without fear of direct interference with our cellular functions. This is in particular because all these technological utilities are many orders of magnitude larger than typical scales of biological activity. Most of biological activity, from fermentative catalysis to DNA replication takes place on nanoscale. The situation is radically different when the technological goals are building nanoscale size products. All biological processes take place on nanoscale.