Geometric and Electronic Properties of Porphyrin: The Complex and Symmetrical Molecules Giving Color to Life
⸻
1. Introduction: Porphyrin as the Chromatic Architect of Life
Porphyrins are the alchemical blossoms of biochemistry—living mandalas composed of four pyrrole petals, each conjoined by methine stems to form a symmetrical macrocyclic flower. This cyclic tetrapyrrole structure lies at the root of life’s chromatic and energetic architectures. Found at the core of chlorophyll, hemoglobin, cytochromes, and vitamin B12, porphyrins are not merely molecular scaffolds; they are resonant gateways that absorb, transmute, and distribute life’s primal energies—light, oxygen, and electrons.
As naturally planar and aromatic rings with a central coordinating cavity, porphyrins are quantum resonators that unify the vibrational language of light with the geometries of biological function. Their form encodes the logic of sacred symmetry; their function reveals the artistry of energy transfer. In these macrocycles, the poetic and the precise converge—color and breath are born from quantum choreography.
⸻
2. The Geometry of Porphyrin: A Fourfold Mandala
At the heart of porphyrin’s power is its D4h symmetry—a sacred fourfold geometry evoking ancient elemental and directional symbolism. Each of the four pyrrole units aligns at right angles, joined by bridging methine groups to form a nearly perfect square ring—a mandala in molecular form.
The central cavity, circled by four nitrogen atoms, serves as a metaphysical hearth—an alchemical vacancy awaiting the indwelling spirit of a metal ion. This geometrically defined binding site creates metalloporphyrins, each with life-changing properties:
• Magnesium (Mg) → Chlorophyll, transmuting sunlight into sugar.
• Iron (Fe) → Hemoglobin, orchestrating breath and blood.
• Cobalt (Co) → Vitamin B12, guiding cellular development and DNA synthesis.
This is not arbitrary architecture—it is functional sacred geometry. The porphyrin macrocycle is a throne, and the metal ion its sovereign. Their union is a synthesis of Earth and ether, organic chemistry and metallic frequency—a harmonic interface between the living and mineral kingdoms.
⸻
3. Electronic Properties: A Dance of Delocalized Electrons
Porphyrins are not static; they are alive with the fluid music of delocalized electrons. The conjugated π-system—a continuous loop of overlapping p-orbitals—forms a quantum corridor for electron resonance. This π-electron delocalization transforms the molecule into a two-dimensional waveguide, a circular quantum drumhead vibrating with solar and bioelectronic rhythms.
This resonance yields unique optical features:
• Soret Band (~400 nm): Strong absorption in the blue-violet spectrum.
• Q Bands (500–700 nm): Weaker but functionally vital absorption in the red-green range.
These absorptions aren’t mere absorption—they’re invitations. Light excites electrons to higher molecular orbitals, initiating photosynthesis, oxygen binding, and redox reactions. Color arises not as pigment, but as a vibrational fingerprint of electron movement.
The porphyrin thus acts as a biological antenna—receiving solar photons, transducing them into usable energy, and redistributing them through the circuitry of life. Their planar geometry supports quantum coherence, allowing electrons to move with non-local unity—a hallmark of advanced biological systems.
⸻
4. Metalloporphyrins: Alchemical Fusion of Geometry & Metal
When a metal ion embeds itself into the central cavity of the porphyrin ring, a transformation akin to the Philosopher’s Stone occurs. The porphyrin becomes a metalloporphyrin—no longer passive, but catalytic; no longer abstract, but active in the biosphere’s great drama.
Chlorophyll (Mg-porphyrin):
• Harvests sunlight through Mg’s central coordination.
• Initiates photoinduced charge separation—the opening chord of photosynthesis.
• Exhibits green due to specific absorption in red and blue—a visual signature of energy filtering.
Hemoglobin (Fe-porphyrin):
⸻
1. Introduction: Porphyrin as the Chromatic Architect of Life
Porphyrins are the alchemical blossoms of biochemistry—living mandalas composed of four pyrrole petals, each conjoined by methine stems to form a symmetrical macrocyclic flower. This cyclic tetrapyrrole structure lies at the root of life’s chromatic and energetic architectures. Found at the core of chlorophyll, hemoglobin, cytochromes, and vitamin B12, porphyrins are not merely molecular scaffolds; they are resonant gateways that absorb, transmute, and distribute life’s primal energies—light, oxygen, and electrons.
As naturally planar and aromatic rings with a central coordinating cavity, porphyrins are quantum resonators that unify the vibrational language of light with the geometries of biological function. Their form encodes the logic of sacred symmetry; their function reveals the artistry of energy transfer. In these macrocycles, the poetic and the precise converge—color and breath are born from quantum choreography.
⸻
2. The Geometry of Porphyrin: A Fourfold Mandala
At the heart of porphyrin’s power is its D4h symmetry—a sacred fourfold geometry evoking ancient elemental and directional symbolism. Each of the four pyrrole units aligns at right angles, joined by bridging methine groups to form a nearly perfect square ring—a mandala in molecular form.
The central cavity, circled by four nitrogen atoms, serves as a metaphysical hearth—an alchemical vacancy awaiting the indwelling spirit of a metal ion. This geometrically defined binding site creates metalloporphyrins, each with life-changing properties:
• Magnesium (Mg) → Chlorophyll, transmuting sunlight into sugar.
• Iron (Fe) → Hemoglobin, orchestrating breath and blood.
• Cobalt (Co) → Vitamin B12, guiding cellular development and DNA synthesis.
This is not arbitrary architecture—it is functional sacred geometry. The porphyrin macrocycle is a throne, and the metal ion its sovereign. Their union is a synthesis of Earth and ether, organic chemistry and metallic frequency—a harmonic interface between the living and mineral kingdoms.
⸻
3. Electronic Properties: A Dance of Delocalized Electrons
Porphyrins are not static; they are alive with the fluid music of delocalized electrons. The conjugated π-system—a continuous loop of overlapping p-orbitals—forms a quantum corridor for electron resonance. This π-electron delocalization transforms the molecule into a two-dimensional waveguide, a circular quantum drumhead vibrating with solar and bioelectronic rhythms.
This resonance yields unique optical features:
• Soret Band (~400 nm): Strong absorption in the blue-violet spectrum.
• Q Bands (500–700 nm): Weaker but functionally vital absorption in the red-green range.
These absorptions aren’t mere absorption—they’re invitations. Light excites electrons to higher molecular orbitals, initiating photosynthesis, oxygen binding, and redox reactions. Color arises not as pigment, but as a vibrational fingerprint of electron movement.
The porphyrin thus acts as a biological antenna—receiving solar photons, transducing them into usable energy, and redistributing them through the circuitry of life. Their planar geometry supports quantum coherence, allowing electrons to move with non-local unity—a hallmark of advanced biological systems.
⸻
4. Metalloporphyrins: Alchemical Fusion of Geometry & Metal
When a metal ion embeds itself into the central cavity of the porphyrin ring, a transformation akin to the Philosopher’s Stone occurs. The porphyrin becomes a metalloporphyrin—no longer passive, but catalytic; no longer abstract, but active in the biosphere’s great drama.
Chlorophyll (Mg-porphyrin):
• Harvests sunlight through Mg’s central coordination.
• Initiates photoinduced charge separation—the opening chord of photosynthesis.
• Exhibits green due to specific absorption in red and blue—a visual signature of energy filtering.
Hemoglobin (Fe-porphyrin):
Encyclopedia Britannica
porphyrin
Porphyrin, any of a class of water-soluble, nitrogenous biological pigments (biochromes), derivatives of which include the hemoproteins (porphyrins combined with metals and protein). Examples of hemoproteins are the green, photosynthetic chlorophylls of higher…
• Iron’s versatile d-orbitals allow reversible binding of oxygen.
• The oxygenation state changes hemoglobin’s absorption spectrum—red when bound, blue when unbound.
• A perfect demonstration of how geometry and electron configuration create functional biomagic.
Cytochromes:
• Act as quantum switches in electron transport chains.
• Use Fe-porphyrin cores to facilitate oxidation-reduction reactions, converting food into energy.
• Illustrate porphyrins as central nodes in the quantum architecture of respiration.
These are not mere molecules—they are bioenergetic temples, with electrons as worshippers and metal ions as high priests in the altar of life’s unfolding.
⸻
5. Quantum Geometry and Color: Why Porphyrins Radiate
Color is the visible expression of invisible resonance. In porphyrins, this radiance arises from:
• The extent of π-electron delocalization.
• The precise symmetry and orbital interactions of the ring.
• The identity and oxidation state of the central metal ion.
• Peripheral substituents modifying electron density and resonance.
Thus, red blood and green leaves are not cosmetic accidents—they are quantum echoes of specific geometries and electronic harmonies. These molecules encode a chromatic spectrum that resonates across biology, physics, and perception.
Porphyrins reveal that color is geometry made visible—an electromagnetic language through which life communicates its inner order.
⸻
6. Porphyrins in Photosynthesis: Geometry of Light Alchemy
In the photosynthetic machinery of plants, porphyrins form the central nodes of vast light-harvesting antennae. Chlorophyll molecules, nested within membrane-embedded proteins, are arranged in spiral, fractal, or flower-like patterns that maximize photon absorption.
Recent studies show that these complexes exhibit quantum coherence, allowing them to transfer energy with astonishing efficiency. This quantum choreography is guided by the spatial arrangement—the geometry itself ensures that photons traverse the system with minimal entropy.
From photon to sugar, the transformation unfolds through the sacred design of porphyrin-based light-catchers. This is not metaphorical alchemy—it is literal transmutation of solar energy into biomass. Geometry doesn’t just describe this process—it enables it.
⸻
7. Philosophical and Esoteric Reflections
Porphyrins offer a synthesis of spiritual and scientific symbolism:
• Their quaternary symmetry mirrors sacred mandalas, solar crosses, and medicine wheels.
• The central metal is the metaphysical heart—a still point through which change radiates.
• Their function—to channel light, breath, and electrons—is a metaphoric dance of soul and body.
In ancient esoteric terms, porphyrins might be seen as living sigils—symbols through which the universe encoded breath, color, and consciousness. They sit at the intersection of form and function, microcosm and macrocosm, geometry and mystery.
Life does not just contain geometry; it is geometry in motion—electrified, chlorophyllated, hemoglobinated.
⸻
8. Conclusion: Porphyrin as Life’s Resonant Talisman
Porphyrins are resonant talismans—molecular mandalas that anchor light into matter, breath into blood, soul into structure. They are more than bio-functional units; they are sacred designs performing quantum rituals of exchange and transformation.
Their symmetrical ring holds more than a metal ion—it holds the memory of solar fire, the potential of breath, and the logic of color. From the chlorophyll-green pulse of a leaf to the crimson tide of human blood, porphyrins orchestrate the visible spectrum of life.
In their dance of delocalized electrons, they reveal an ancient secret: geometry is not static. It lives, breathes, and sings. And in porphyrins, that song is the chromatic breath of the biosphere itself.
1. Introduction: Porphyrin as the Chromatic Architect of Life
• Britannica. (n.d.). Porphyrin. Retrieved from https://www.britannica.com/science/porphyrin
• The oxygenation state changes hemoglobin’s absorption spectrum—red when bound, blue when unbound.
• A perfect demonstration of how geometry and electron configuration create functional biomagic.
Cytochromes:
• Act as quantum switches in electron transport chains.
• Use Fe-porphyrin cores to facilitate oxidation-reduction reactions, converting food into energy.
• Illustrate porphyrins as central nodes in the quantum architecture of respiration.
These are not mere molecules—they are bioenergetic temples, with electrons as worshippers and metal ions as high priests in the altar of life’s unfolding.
⸻
5. Quantum Geometry and Color: Why Porphyrins Radiate
Color is the visible expression of invisible resonance. In porphyrins, this radiance arises from:
• The extent of π-electron delocalization.
• The precise symmetry and orbital interactions of the ring.
• The identity and oxidation state of the central metal ion.
• Peripheral substituents modifying electron density and resonance.
Thus, red blood and green leaves are not cosmetic accidents—they are quantum echoes of specific geometries and electronic harmonies. These molecules encode a chromatic spectrum that resonates across biology, physics, and perception.
Porphyrins reveal that color is geometry made visible—an electromagnetic language through which life communicates its inner order.
⸻
6. Porphyrins in Photosynthesis: Geometry of Light Alchemy
In the photosynthetic machinery of plants, porphyrins form the central nodes of vast light-harvesting antennae. Chlorophyll molecules, nested within membrane-embedded proteins, are arranged in spiral, fractal, or flower-like patterns that maximize photon absorption.
Recent studies show that these complexes exhibit quantum coherence, allowing them to transfer energy with astonishing efficiency. This quantum choreography is guided by the spatial arrangement—the geometry itself ensures that photons traverse the system with minimal entropy.
From photon to sugar, the transformation unfolds through the sacred design of porphyrin-based light-catchers. This is not metaphorical alchemy—it is literal transmutation of solar energy into biomass. Geometry doesn’t just describe this process—it enables it.
⸻
7. Philosophical and Esoteric Reflections
Porphyrins offer a synthesis of spiritual and scientific symbolism:
• Their quaternary symmetry mirrors sacred mandalas, solar crosses, and medicine wheels.
• The central metal is the metaphysical heart—a still point through which change radiates.
• Their function—to channel light, breath, and electrons—is a metaphoric dance of soul and body.
In ancient esoteric terms, porphyrins might be seen as living sigils—symbols through which the universe encoded breath, color, and consciousness. They sit at the intersection of form and function, microcosm and macrocosm, geometry and mystery.
Life does not just contain geometry; it is geometry in motion—electrified, chlorophyllated, hemoglobinated.
⸻
8. Conclusion: Porphyrin as Life’s Resonant Talisman
Porphyrins are resonant talismans—molecular mandalas that anchor light into matter, breath into blood, soul into structure. They are more than bio-functional units; they are sacred designs performing quantum rituals of exchange and transformation.
Their symmetrical ring holds more than a metal ion—it holds the memory of solar fire, the potential of breath, and the logic of color. From the chlorophyll-green pulse of a leaf to the crimson tide of human blood, porphyrins orchestrate the visible spectrum of life.
In their dance of delocalized electrons, they reveal an ancient secret: geometry is not static. It lives, breathes, and sings. And in porphyrins, that song is the chromatic breath of the biosphere itself.
1. Introduction: Porphyrin as the Chromatic Architect of Life
• Britannica. (n.d.). Porphyrin. Retrieved from https://www.britannica.com/science/porphyrin
Encyclopedia Britannica
porphyrin
Porphyrin, any of a class of water-soluble, nitrogenous biological pigments (biochromes), derivatives of which include the hemoproteins (porphyrins combined with metals and protein). Examples of hemoproteins are the green, photosynthetic chlorophylls of higher…
This article provides an overview of porphyrins, discussing their structure, function, and significance in biological systems.
• Senge, M. O., & Smith, K. M. (2019). Photocatalytic redox reactions with metalloporphyrins. Journal of Porphyrins and Phthalocyanines, 23(6), 1–15. https://doi.org/10.1142/S1088424619300131
This paper discusses the role of metalloporphyrins in photocatalytic redox reactions, highlighting their importance in mimicking photosynthetic processes.
⸻
2. The Geometry of Porphyrin: A Fourfold Mandala
• Gouterman, M. (1961). Spectra of porphyrins. Journal of Molecular Spectroscopy, 6(1), 138–163. https://doi.org/10.1016/0022-2852(61)90236-3
Gouterman’s work provides foundational insight into the spectral properties of porphyrins, relating their geometry to their electronic transitions.
• Senge, M. O. (2000). The conformational flexibility of tetrapyrroles: Lessons from porphyrins and chlorophylls. Chemical Communications, (22), 2001–2009. https://doi.org/10.1039/B005892K
This article explores the conformational aspects of porphyrins and their relevance to biological functions.
⸻
3. Electronic Properties: A Dance of Delocalized Electrons
• Wiethorn, Z. R., Hunter, K. E., Montoya-Castillo, A., & Zuehlsdorff, T. J. (2024). Symmetry breaking fluctuations split the porphyrin Q bands. arXiv preprint arXiv:2411.02687. https://arxiv.org/abs/2411.02687
This study investigates the electronic spectra of porphyrins, focusing on the Q-band splitting due to symmetry-breaking fluctuations.
• Gouterman, M. (1978). Optical spectra and electronic structure of porphyrins and related rings. In The Porphyrins (Vol. 3, pp. 1–165). Academic Press.
Gouterman’s comprehensive review details the electronic structure of porphyrins and their optical properties.
⸻
4. Metalloporphyrins: Alchemical Fusion of Geometry & Metal
• Balaban, T. S. (2005). Modeling of artificial photosynthetic systems. Accounts of Chemical Research, 38(8), 612–623. https://doi.org/10.1021/ar040244w
This article discusses the design of artificial photosynthetic systems using metalloporphyrins, emphasizing their catalytic roles.
• Kadish, K. M., Smith, K. M., & Guilard, R. (Eds.). (2000). The Porphyrin Handbook (Vols. 1–10). Academic Press.
A comprehensive reference covering the chemistry, biology, and applications of porphyrins and metalloporphyrins.
⸻
5. Quantum Geometry and Color: Why Porphyrins Radiate
• Senge, M. O., MacGowan, S. A., & O’Brien, J. M. (2015). Conformational control of cofactors in nature – The influence of protein-induced macrocycle distortion on the biological function of tetrapyrroles. Chemical Communications, 51(70), 17031–17063. https://doi.org/10.1039/C5CC06218A
This paper explores how the geometry of porphyrins influences their electronic properties and color manifestation.
• Gouterman, M. (1978). Optical spectra and electronic structure of porphyrins and related rings. In The Porphyrins (Vol. 3, pp. 1–165). Academic Press.
As previously mentioned, this work is fundamental in understanding the relationship between porphyrin geometry and their optical spectra.
⸻
6. Porphyrins in Photosynthesis: Geometry of Light Alchemy
• Blankenship, R. E. (2014). Molecular Mechanisms of Photosynthesis (2nd ed.). Wiley-Blackwell.
This book provides an in-depth look at the role of porphyrins in photosynthesis, detailing the structural and functional aspects of light-harvesting complexes.
• Senge, M. O., & Smith, K. M. (2019). Photocatalytic redox reactions with metalloporphyrins. Journal of Porphyrins and Phthalocyanines, 23(6), 1–15. https://doi.org/10.1142/S1088424619300131
This article, also cited in the introduction, discusses the application of metalloporphyrins in mimicking photosynthetic reactions.
⸻
7. Philosophical and Esoteric Reflections
• Jung, C. G. (1959). The Archetypes and the Collective Unconscious. Princeton University Press.
Jung’s work on archetypes provides a psychological perspective that can be related to the symbolic interpretations of porphyrin structures.
• Eliade, M. (1959).
• Senge, M. O., & Smith, K. M. (2019). Photocatalytic redox reactions with metalloporphyrins. Journal of Porphyrins and Phthalocyanines, 23(6), 1–15. https://doi.org/10.1142/S1088424619300131
This paper discusses the role of metalloporphyrins in photocatalytic redox reactions, highlighting their importance in mimicking photosynthetic processes.
⸻
2. The Geometry of Porphyrin: A Fourfold Mandala
• Gouterman, M. (1961). Spectra of porphyrins. Journal of Molecular Spectroscopy, 6(1), 138–163. https://doi.org/10.1016/0022-2852(61)90236-3
Gouterman’s work provides foundational insight into the spectral properties of porphyrins, relating their geometry to their electronic transitions.
• Senge, M. O. (2000). The conformational flexibility of tetrapyrroles: Lessons from porphyrins and chlorophylls. Chemical Communications, (22), 2001–2009. https://doi.org/10.1039/B005892K
This article explores the conformational aspects of porphyrins and their relevance to biological functions.
⸻
3. Electronic Properties: A Dance of Delocalized Electrons
• Wiethorn, Z. R., Hunter, K. E., Montoya-Castillo, A., & Zuehlsdorff, T. J. (2024). Symmetry breaking fluctuations split the porphyrin Q bands. arXiv preprint arXiv:2411.02687. https://arxiv.org/abs/2411.02687
This study investigates the electronic spectra of porphyrins, focusing on the Q-band splitting due to symmetry-breaking fluctuations.
• Gouterman, M. (1978). Optical spectra and electronic structure of porphyrins and related rings. In The Porphyrins (Vol. 3, pp. 1–165). Academic Press.
Gouterman’s comprehensive review details the electronic structure of porphyrins and their optical properties.
⸻
4. Metalloporphyrins: Alchemical Fusion of Geometry & Metal
• Balaban, T. S. (2005). Modeling of artificial photosynthetic systems. Accounts of Chemical Research, 38(8), 612–623. https://doi.org/10.1021/ar040244w
This article discusses the design of artificial photosynthetic systems using metalloporphyrins, emphasizing their catalytic roles.
• Kadish, K. M., Smith, K. M., & Guilard, R. (Eds.). (2000). The Porphyrin Handbook (Vols. 1–10). Academic Press.
A comprehensive reference covering the chemistry, biology, and applications of porphyrins and metalloporphyrins.
⸻
5. Quantum Geometry and Color: Why Porphyrins Radiate
• Senge, M. O., MacGowan, S. A., & O’Brien, J. M. (2015). Conformational control of cofactors in nature – The influence of protein-induced macrocycle distortion on the biological function of tetrapyrroles. Chemical Communications, 51(70), 17031–17063. https://doi.org/10.1039/C5CC06218A
This paper explores how the geometry of porphyrins influences their electronic properties and color manifestation.
• Gouterman, M. (1978). Optical spectra and electronic structure of porphyrins and related rings. In The Porphyrins (Vol. 3, pp. 1–165). Academic Press.
As previously mentioned, this work is fundamental in understanding the relationship between porphyrin geometry and their optical spectra.
⸻
6. Porphyrins in Photosynthesis: Geometry of Light Alchemy
• Blankenship, R. E. (2014). Molecular Mechanisms of Photosynthesis (2nd ed.). Wiley-Blackwell.
This book provides an in-depth look at the role of porphyrins in photosynthesis, detailing the structural and functional aspects of light-harvesting complexes.
• Senge, M. O., & Smith, K. M. (2019). Photocatalytic redox reactions with metalloporphyrins. Journal of Porphyrins and Phthalocyanines, 23(6), 1–15. https://doi.org/10.1142/S1088424619300131
This article, also cited in the introduction, discusses the application of metalloporphyrins in mimicking photosynthetic reactions.
⸻
7. Philosophical and Esoteric Reflections
• Jung, C. G. (1959). The Archetypes and the Collective Unconscious. Princeton University Press.
Jung’s work on archetypes provides a psychological perspective that can be related to the symbolic interpretations of porphyrin structures.
• Eliade, M. (1959).
Encyclopedia Britannica
porphyrin
Porphyrin, any of a class of water-soluble, nitrogenous biological pigments (biochromes), derivatives of which include the hemoproteins (porphyrins combined with metals and protein). Examples of hemoproteins are the green, photosynthetic chlorophylls of higher…
The Sacred and the Profane: The Nature of Religion. Harcourt.
8.Scroll & Final research
• Lincoln Xavier N. N. (2025). SACRED GEOMETRY - BEYOND THE EYES. Scientific reasearch available at Universidade de Brasilia
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https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com
8.Scroll & Final research
• Lincoln Xavier N. N. (2025). SACRED GEOMETRY - BEYOND THE EYES. Scientific reasearch available at Universidade de Brasilia
🔵⚪️🔴
https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com
Encyclopedia Britannica
porphyrin
Porphyrin, any of a class of water-soluble, nitrogenous biological pigments (biochromes), derivatives of which include the hemoproteins (porphyrins combined with metals and protein). Examples of hemoproteins are the green, photosynthetic chlorophylls of higher…
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RFK JR: Sie haben unser Nahrungsmittelsystem so verändert, dass es Gift für uns ist
Sie essen keine Nahrung, sondern lebensmittelähnliche Substanzen, die dafür entwickelt wurden, dass Sie sich immer hungrig fühlen – Sie haben das menschliche Gehirn gekapert
Wissenschaftler haben herausgefunden, dass Ihr Gehirn Ihrem Magen anhand der Häufigkeit des Kauens mitteilt, dass er voll ist.
Und was haben sie getan? Sie haben Weichmacher hinzugefügt, damit man nie das Gefühl hat, satt zu sein.
Die meisten werden diese Nachricht ignorieren.
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https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com
Sie essen keine Nahrung, sondern lebensmittelähnliche Substanzen, die dafür entwickelt wurden, dass Sie sich immer hungrig fühlen – Sie haben das menschliche Gehirn gekapert
Wissenschaftler haben herausgefunden, dass Ihr Gehirn Ihrem Magen anhand der Häufigkeit des Kauens mitteilt, dass er voll ist.
Und was haben sie getan? Sie haben Weichmacher hinzugefügt, damit man nie das Gefühl hat, satt zu sein.
Die meisten werden diese Nachricht ignorieren.
🔵⚪️🔴
https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com
Noch nie in meinem Leben habe ich so viel Hass auf zwei Männer erlebt, die versuchen, Amerikas Zukunft zu retten.
Ich stehe an der Seite von Präsident Trump und Elon Musk!
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https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com
Ich stehe an der Seite von Präsident Trump und Elon Musk!
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https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com
Fauci, Birx und andere COVID-Beamte werden in sieben Bundesstaaten wegen Mordes und anderer Anklagen verfolgt
https://www.infowars.com/posts/fauci-birx-and-other-covid-officials-pursued-for-murder-and-other-charges-in-seven-states
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https://www.infowars.com/posts/fauci-birx-and-other-covid-officials-pursued-for-murder-and-other-charges-in-seven-states
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Großeinsatz gegen Kindesmissbrauch in Rheinland-Pfalz
"Insgesamt richteten sich die Ermittlungen im Land gegen 49 Personen 47 Männer und zwei Frauen.
Allein in den Bereichen der Polizeipräsidien Mainz und Koblenz gab es jeweils 14 Durchsuchungen, acht im Präsidium Rheinpfalz, drei im Präsidium Trier und zwei im Bereich Westpfalz."
https://www.swr.de/swraktuell/rheinland-pfalz/grosseinsatz-der-polizei-gegen-kindesmissbrauch-100.html
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https://t.me/GHZFriedrichMaik
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"Insgesamt richteten sich die Ermittlungen im Land gegen 49 Personen 47 Männer und zwei Frauen.
Allein in den Bereichen der Polizeipräsidien Mainz und Koblenz gab es jeweils 14 Durchsuchungen, acht im Präsidium Rheinpfalz, drei im Präsidium Trier und zwei im Bereich Westpfalz."
https://www.swr.de/swraktuell/rheinland-pfalz/grosseinsatz-der-polizei-gegen-kindesmissbrauch-100.html
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https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com
SWR Aktuell
Großeinsatz gegen Kindesmissbrauch in Rheinland-Pfalz
Bei einer internationalen Aktion gegen Kindesmissbrauch hat die Polizei in Rheinland-Pfalz 41 Objekte durchsucht. Dabei wurde ein Mann im Kreis Alzey-Worms festgenommen. Die Ermittlungen laufen.
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Vivaldi integriert ProtonVPN.
Kostenloser Schutz gegen Web-Tracking.
Der Vivaldi-Browser erhält ein mächtiges Datenschutz-Upgrade: ProtonVPN ist ab sofort direkt integriert – ohne Add-ons oder Plugins. Nutzer surfen dadurch verschlüsselt und anonym, völlig kostenlos.
Das Schweizer VPN kommt ohne Werbung, ohne Zeit- oder Datenlimits. Hinter dem Projekt steht eine Non-Profit-Organisation, die sich als unabhängig von politischem Einfluss versteht.
Die Integration schützt zwar nur den Browser-Verkehr, zeigt aber, dass europäische Firmen echte Gegenmodelle zu Big Tech liefern – ein bedeutender Schritt für digitale Souveränität und Privatsphäre.
Wer gesamten Systemverkehr absichern will, sollte zusätzlich eine eigene VPN Struktur aufbauen – erst damit ist vollständiger Schutz möglich.
Quelle
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Kostenloser Schutz gegen Web-Tracking.
Der Vivaldi-Browser erhält ein mächtiges Datenschutz-Upgrade: ProtonVPN ist ab sofort direkt integriert – ohne Add-ons oder Plugins. Nutzer surfen dadurch verschlüsselt und anonym, völlig kostenlos.
Das Schweizer VPN kommt ohne Werbung, ohne Zeit- oder Datenlimits. Hinter dem Projekt steht eine Non-Profit-Organisation, die sich als unabhängig von politischem Einfluss versteht.
Die Integration schützt zwar nur den Browser-Verkehr, zeigt aber, dass europäische Firmen echte Gegenmodelle zu Big Tech liefern – ein bedeutender Schritt für digitale Souveränität und Privatsphäre.
Wer gesamten Systemverkehr absichern will, sollte zusätzlich eine eigene VPN Struktur aufbauen – erst damit ist vollständiger Schutz möglich.
Quelle
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https://t.me/GHZFriedrichMaik
www.ghz-friedrich-maik.com