DHS is comprised of 22 departments and agencies, and four main directorates: Border and Transportation Security, Emergency Preparedness, Science and Technology, and Information Analysis and Infrastructure Protection. Since DHS was established, it has faced a broader range of challenges. This includes natural disasters such as the global pandemic, hurricanes, wildfires, widespread cyberattacks, domestic terrorism, and the expansion of transnational criminal activities. These are examples of threats and hazards that are central to homeland security. The most recent are non-military threats like election interference and disinformation that are increasingly important and will continue to be a priority even after the 2020 election. In addition, climate change is gradually impacting U.S. critical infrastructure and prosperity. Question: This week we reviewed the role of long-term strategy and priorities for homeland security. Is the current organizational structure and strategy for DHS adequate to meet the broader range of challenges and threats over the next decade? Must be based on factual academic information (not personal opinion) supported with citations to at least two (2) academic references
Homeland Security, Intelligence & Strategy Discussion
Since it was formed in 2003, the Department of Homeland Security (DHS) has achieved significant progress across its key mission areas: preventing terrorism; securing our borders; enforcing our immigration laws; securing cyberspace; and ensuring resilience to disasters. The U.S. Department of Homeland Security remains vigilant and forward-looking, prepared to adapt and evolve to multiple threats and crises, just as the threats the department confront adapt evolve. The department will safeguard the American people, our Homeland, and our values with honor and integrity. The source and nature of the terrorist threat may have expanded, but the department will continue to fight to ensure that all Americans are able to live free from the fear of violence, no matter the ideology behind it (DHS).
The most common three methods used to prepare the nanoparticles are: (1) dispersion of preformed polymers; (2) direct polymerization of monomers using classical polymerization reactions; and (3) ionic gelation or coacervation of hydrophilic polymers. However, other methods like supercritical fluid technology [140] and particle replication in non-wetting templates (PRINT) [141] can be also used to prepare nanoparticles.
Polymeric nanoparticles (PNPs) can be prepared from preformed polymers through several methods such as solvent evaporation, salting-out, dialysis and supercritical fluid technology which involving the rapid expansion of a supercritical solution or rapid expansion of a supercritical solution into a liquid solvent. In contrast, PNPs can be directly synthesized through the polymerization of monomers using a variety of polymerization techniques like mini-emulsion, micro-emulsion, surfactant-free emulsion and interfacial polymerization.
The choice of preparation method is made on the basis of a number of factors such as the type of polymeric systems, the area of application, size requirement, and the drug to be loaded. Since, method of preparation mainly affect the properties of produced nanoparticles, it is highly advantageous to have preparation techniques at hand to get PNPs with the required properties for a particular application.
The term nanoprecipitation refers to a quite simple processing method for the fabrication of polymeric nanoparticles. The level of interest in nanoprecipitation waned for some decades, and the method regained recognition in the 50’s as a means of preparing colloids for stabilizing pigments [142], as well as industrially important components in paints, lacquers, and other coatings [142], While it had already been reported at least as early as the 1940’s as a way for isolation of purified analytical samples of synthetic polymers , nanoprecipitation regained a heightened level of patent interest in the 1950’s and 60’s this time as a cost effective method for purifying synthetic polyolefins [142].
In the late 80’s and early 90’s, Fessi et al.,1989 [143] patented the nanoprecipitation method as a procedure for the preparation of eligible colloidal systems of a polymeric substance in the form of nanoparticles [143].
Nanoprecipitation is also called solvent displacement method or interfacial precipitation method [143-148] .It depends on the precipitation of a preformed polymer from an organic solution and the diffusion of the organic solvent in the aqueous phase either in the presence or absence of a surfactant [143, 149-151].
The main principle of this technique is based on the interfacial deposition of a polymer after displacement of a semi polar solvent, miscible with water, from a lipophilic solution. Rapid diffusion of the solvent into non-solvent phase results in the decrease of interfacial tension between the two phas