The creation of an anti-Covid-19 vaccine at warp speed disregards the non-immunological anti-virus defense reaction mediated by the pathway of cellular energy choice (ACE). In studies on stealth adapted viruses, this pathway was established. Inside the genes, these viruses have deletions or mutations coding for the very few components of the virus that the cellular system usually targets. The existence of these viruses has been disputed by public health officials because some were originally developed from viruses that infect monkeys and do not yield polio vaccines. A truly unusual feature of the stealth adaptation process is that there is always the inclusion of genetic sequences from infected cells in addition to losing those genes. This has caused monkey cellular genes to be transferred to humans.
While the system’s ability to suppress stealth-adapted viruses is minimal, these viruses, and indeed probably all viruses, can still be suppressed, providing adequate cellular energy for the infected cells. Therefore, symptomatic Covid-19 infection is an indication that the cells of the individual have inadequate cellular capacity. Conversely, by enhancing the cellular energy of those exposed to the virus, symptomatic infections are also avoided. This will likely be done by repeated inhalation of the mist formed by inhalation of nebulizing water with an increased amount of natural energy referred to as KLELEA, an abbreviation for K.E. Electrostatic Attraction Constraint. In Southern California, a natural source of KELEA activated water has been found. It can also be generated using a variety of straightforward methods. The latest forensic procedure is to inhale the mist from 5 ml of activated water for 2 days over a period of 5 minutes five times a day. The first result is the conversion from a positive PCR or antigen test to a negative test after the investigational procedure before the two-day inhalation. Self-reported measurements of improvements in symptom severity are a secondary result.
Stealth-adapted individuals infected with viruses are at a special risk of obtaining a vaccine against Covid-19. Second, the vaccine’s non-specific immune stimulation will allow for immune reactivity against a variety of residual components of viruses adapted to stealth. The resulting inflammation may occur as MS or transverse myelitis if these viruses exist within the central nervous system, as has been documented using the AstraZeneca vaccine. Second, viruses adapted to stealth may introduce foreign genes and become carriers of them. If pre-existing stealth-adapted viruses were to contain the COVID-19 PCR TEST at home spike antigen-coding DNA or RNA sequence vaccine, they could easily interrupt the regulatory mechanism regulated by angiotensin in the body. It is extremely unlikely that both the Food and Drug Administration (FDA) or vaccine manufacturers will answer those considerations. Indeed, as noted above, in spite of overwhelming DNA sequence data on these viruses, the FDA, and even the National Institutes of Health (NIH), have failed to even recognize the presence of monkey-derived stealth-adapted viruses.
It’s completely unnecessary to vaccinate anyone for a disease that causes symptoms in just a tiny percentage of those infected. What is more reasonable is to have the means to reduce the vulnerability of anyone who may otherwise acquire a symptomatic disease. In addition to the immediate inhalation of activated water from KELEA, advantages tend to derive from the easy wearing of small pouches containing activated water. Similarly, it is possible for activated water to humidify closed living spaces. The location of sources of naturally activated water promotes these approaches.
In human history, pandemics often end up with untold and often unprecedented problems that would require great thinkers to provide solutions. Researchers are positive opportunists that do not relent in their attempts to constantly examine the ‘what’,’ where’,’ who’ and ‘how’ in each case primarily to provide humanity with relief. In the current outbreak, researchers in different disciplines must consider how to provide the outbreak with a substitute lens of understanding and, more specifically, provide immediate solutions to its related challenges that threaten human survival structures.
After the emergence of the global COVID-19 pandemic, scientists have begun to examine the etiology, epidemiology, pathophysiology, histopathology, clinical evaluation/treatment/management and diagnosis of COVID-19 within the area of Health and Allied Sciences. A analysis of the academic work in this field shows great contributions from Asian scientists, especially from China, where the outbreak began. In their attempts to medically investigate what can be done to combat the virus, these hardworking researchers have never relented. Even under perilous working conditions that resulted in the loss of others, these outstanding researchers continued to follow this direction. They need to really explain and demonstrate what researchers need to do all the time to continuously verify solutions to relieve their fellow humans’ suffering even in pandemic times. More needs to be achieved by their counterparts in other countries, however. There is a need for medical scientists in many regions of the world to study the genome sequence of the novel coronavirus. Interestingly, other drug scientists are busily researching this phenomenon to educate the coronavirus knowledgeably, suggesting preventive steps and, more importantly, seeking medical cure and vaccine to tackle it entirely. As an example, while medical scientists are searching through the lens of orthodox medicine, herbal practitioners are experimenting with ways to generate medicine using herbal extracts that will improve the system and/or provide a robust immune buffer to combat the coronavirus. Such attempts are commendable. More work needs to be done to check for more reliable ways of performing COVID-19 patient checks, completing touch tracking, and coronavirus precautionary/preventive steps.
Engineering researchers, particularly computer scientists and engineers, are developing technologies to help mitigate the spread of COVID-19. In some nations, emerging technology such as drones and robocops are developed and used, to sum up, to manually execute lockdowns. Similarly, mobile technologies are also being designed as those that have had experience with them, such as the incidence of recent contact tracing applications for COVID-19 patients. As an example, MIT researchers are developing a system funded by AI to improve the manual communication tracing of short-range Bluetooth signals from smartphones administered by public health personnel. In South Africa, ambulances equipped with automated test kits and laboratory facilities are used to test and monitor individuals with COVID-19, also in rural, hard-to-reach areas, as a result of diligent research efforts. The Ministry of Health recently introduced the COVID-19 app in Ghana to monitor people infected or who have had contact with COVID-19 virus carriers. These technologies, developed by some mechanical engineers as a result of comprehensive studies, are also deployed as hardware and software engineers to assist in the battle against COVID-19. More technical resources are also needed to combat the coronavirus, and committed engineering researchers are continuously on the table researching these potentialities.
Agriculture researchers have a wonderful research assignment at their hands. The lockout resulted in countries having a high record of post-harvest losses. What are the most powerful ways to reduce post-harvest losses during pandemic and lockout times? How will farmers use online marketing tactics and channels to communicate with consumers to patronize their goods to avoid high financial losses from occurring? What will the Food and Agriculture Ministry do to help these poor farmers cope with the lockdown crisis? What are some of the productive ways in which food processing companies can turn perishable farm products into non-perishable products? These are excellent themes that warrant agriculturalists’ investigation during this pandemic outbreak. Unfortunately, research in these fields have yet to be undertaken.
Thanks to the COVID-19 pandemic, the tourism and hospitality management industry has been significantly affected. Thanks to travel restrictions and lockdowns, several planned tours and tourist events are cancelled. It is predicted that the global tourism industry will lose a high turnover of up to two billion dollars on the brink. This is also the moment when researchers in tourism and hospitality management, through intensified research into smart tourism and e-tourism, may consider virtual means of selling these tourism sites. Not much attention has been given to this growing area of tourism, especially in developing countries. This pandemic time should be the moment when researchers can find ways to increase public understanding of smart tourism and e-tourism in this region.
