Dark Field Microscopy by Dr David Nixon ~ Team Enigma Nov 3, 2022
Dr. David Nixon joins us to reveal footage NEVER before seen anywhere in the world – real time footage of the nanotechnology inside the COVID-19 injections assembling robotic arms that guide the nanotechnology development.
Mike Andersen:
“The analysis of the images obtained by the doctor (Campra, P. 2021) continues to focus on the detection of nanotechnology, circuits and chips, according to the latest findings, regarding the highly probable presence of nanorouters . On this occasion, a recurring pattern in the shape of a Balkan cross has been found that could be reminiscent of triangular blades, oriented towards a common vertex or confluence, see figure 1.”
“Actually, the pattern corresponds to a plasmonic nano-antenna in the shape of a double bow tie or a four-leaf bow tie, as referred to in the scientific literature (Chau, YFC; Chao, CTC; Rao, JY; Chiang, HP; Lim, CM; Lim, RC; Voo, NY 2016 | Ahmadivand, A .; Sinha, R .; Pala, N. 2015 | Gupta, N .; Dhawan, A. 2018) with the terminology “quad-triangles nanoantenna” and “plasmonic bowtie” .”
“Fig. 7. Identification of graphene octopuses that can be developed from carbon nanotubes or linked. The images from the scientific literature are found in the study of (Dasgupta, K .; Joshi, JB; Paul, B .; Sen, D .; Banerjee, S. 2013). The high resolution image can be obtained in this link”
“The most striking object in the c0r0n @ v | rus vaccine samples is the one seen in figures 2 and 6,
which resemble the shape of a polyp with its tentacles (such as hydra attenuata or hydra vulgaris ).
It is actually a carbon octopus, as has been verified in the references of (Dasgupta, K .; Joshi, JB;
Paul, B .; Sen, D .; Banerjee, S. 2013) and (Sharon, M .; Sharon, M. 2006) in Figures 7 and 9. The
shape of the tentacles is very similar and their conformation is derived from carbon nanotubes.”
“Fig. 10. Identification of single and multiple walled graphene nanotubes in the scientific literature. Its presence is checked in c0r0n @ v | rus vaccines. The envelope of the links or junctions between the nanotubes is also observed (indicated in the green squares).”
“Another recurring object in the images taken from the samples of the c0r0n @ v | rus vaccines are filaments of variable length, thickness, density and color, with a certain flexibility in their shapes. As can be seen in figures 1, 4 and 5. These objects have been identified as carbon nanotubes, which means that they are actually graphene tubes, as indicated in figure 8. Carbon nanotubes can be single-walled (single-walled carbon nanotubes SWCNTs) or multi-walled (multi-walled carbon nanotubes MWCNTs). The images in figure 10 show the difference and it is contrasted with the scientific literature.”
so far:
probable.
1. plasmonic nanoantenna
2. nanorouter
3. graphene quantum dot
4. graphene octopuses
5. single and multiple walled graphene nanotubes
Identification of patterns in c0r0n @ v | rus vaccines: self-propelled colloidal nano-worms
“Fig. 1. Worm-like pattern, with its own movement, observed in the vaccine. Image obtained by Dr. Campra.
Fig. 2. The nano-worm is a swimmer-type nano-robot formed by homogeneous spheroids or colloids or with a larger spheroid head, as observed in the vaccine sample. Colloids are bead-linked by proteins and DNA, although this is also possible through the paramagnetic properties of the material used.”
….
“A new pattern has recently been identified, observed in samples of the c0r0n @ v | rus vaccines, specifically the one referred to in figure 1, an image obtained by the doctor (Campra, P. 2021) that was presented in the program 149 of the Fifth Column (Delgado, R .; Sevillano, JL 2021). Analyzing the image, a flagellar body made up of beads is observed, small spheres of a similar size, headed by a larger sphere. The shape is reminiscent of a ” Streptococcus ” type bacterium , however, after comparing all species of the genus, a conclusive coincidence was not found.”
….
“The object observed in figure 1 is actually a self-propelled autonomous nano-robot, specifically it corresponds to a swimmer with anisotropic colloidal rotors linked to DNA, composed of paramagnetic colloidal particles of different or similar size, as they refer (Tierno, P .; Golestanian, R .; Pagonabarraga, I .; Sagués, F. 2008) in his publication ” Magnetically Actuated Colloidal Microswimmers “, see comparison in figure 2 and video 2 of the tests carried out. In the scientific literature, it will also adopt other names, such as ” self-propelled colloidal microworm “, see the reference ( Martínez-Pedrero, F .; Ortiz-Ambriz, A .; Pagonabarraga, I .; Tierno, P. 2015 ).”
Fig. 10. Comparison of PVA (Polyvinyl Alcohol) observed in scientific literature and in vaccine samples. The profile of the PVA bubble in the form of a hydrogel and its angle of incidence are also appreciated, also compatible with the shape of the images analyzed. The upper right box corresponds to an image obtained by Dr. Zandre Botha in the program of (Peters, S. 2021 ). The lower right box corresponds to an image obtained by the doctor (Campra 2021)
Analyzing the properties of PVA (Polyvinyl Alcohol), its conductive capacity is discovered (Chaudhuri, B .; Mondal, B .; Ray, SK; Sarkar, SC 2016), as well as its function as an electrode when combined with other materials ( Liu, S .; Zheng, Y .; Qiao, K .; Su, L .; Sanghera, A .; Song, W .; Sun, Y. 2015 ), specifically with multi-walled carbon nanotubes and by extension graphene, with which they are bathed or covered ( Malikov, EY; Muradov, MB; Akperov, OH; Eyvazova, GM; Puskás, R .; Madarász, D .; Kónya, Z. 2014). All this allows us to infer that PVA bubbles, even in the form of hydrogel, are capable of being controlled and directed by magnetic fields and electric currents, which further strengthens the possibility that PVA bubble beads can be configured and even formed. groups of bubbles due to the capillarity effect and magnetism, due to the Janus effect, whereby each bubble has an opposite pole that serves both to attract other bubbles and to move ( Jian, H .; Qi, Q .; Wang, W .; Yu, D. 2021 | Wang, M .; Yu, DG; Li, X .; Williams, GR 2020 ).