818 results on '"Quantum Biology"'
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52. Fascial Manual Medicine: A Continuous Evolution.
- Author
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Bordoni B and Escher AR
- Abstract
From the perspective of fascial manual medicine (FMM), the body should not be considered as a set of compartments, but as a functional continuum, where most of the tissues (considering embryology) are fascia. The cells that make up the fascia can use multiple strategies to communicate, with neighboring cells, with the tissue to which they belong, and with the entire body, thanks to biochemical (microscopy) and electromagnetic (nanoscopy) possibilities. These multiple capacities to send and receive information make the border or layer of the different tissues seem absent. All the manual techniques that profess to be the only ones that work on the patient's symptoms, dictating a standardized manual procedure that all patients should undergo, represent a clinical deviation. Likewise, thinking that the manual approach can provide biomechanical stimuli only to a single specific structure or layer is a conceptual error. This narrative review briefly reviews the history of fascial-related nomenclature and how the fascial system is currently considered, posing new reflections on how the fascial continuum could be conceived by practitioners who apply FMM in the clinic, such as osteopaths, chiropractors, and physiotherapists., Competing Interests: Conflicts of interest: In compliance with the ICMJE uniform disclosure form, all authors declare the following: Payment/services info: All authors have declared that no financial support was received from any organization for the submitted work. Financial relationships: All authors have declared that they have no financial relationships at present or within the previous three years with any organizations that might have an interest in the submitted work. Other relationships: All authors have declared that there are no other relationships or activities that could appear to have influenced the submitted work., (Copyright © 2024, Bordoni et al.)
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- 2024
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53. Construction and Application of a Static Magnetic Field Exposure Apparatus for Biological Research in Aqueous Model Systems and Cell Culture.
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Vučković J, Gurhan H, Gutierrez B, Guerra J, Kinsey LJ, Nava I, Fitzpatrick A, Barnes FS, Tseng KA, and Beane WS
- Abstract
With the growth of the quantum biology field, the study of magnetic field (MF) effects on biological processes and their potential therapeutic applications has attracted much attention. However, most biologists lack the experience needed to construct an MF exposure apparatus on their own, no consensus standard exists for exposure methods, and protocols for model organisms are sorely lacking. We aim to provide those interested in entering the field with the ability to investigate static MF effects in their own research. This protocol covers how to design, build, calibrate, and operate a static MF exposure chamber (MagShield apparatus), with instructions on how to modify parameters to other specific needs. The MagShield apparatus is constructed of mu-metal (which blocks external MFs), allowing for the generation of experimentally controlled MFs via 3-axial Helmholtz coils. Precise manipulation of static field strengths across a physiologically relevant range is possible: nT hypomagnetic fields, μT to < 1 mT weak MFs, and moderate MFs of several mT. An integrated mu-metal partition enables different control and experimental field strengths to run simultaneously. We demonstrate (with example results) how to use the MagShield apparatus with Xenopus , planarians, and fibroblast/fibrosarcoma cell lines, discussing the modifications needed for cell culture systems; however, the apparatus is easily adaptable to zebrafish, C. elegans , and 3D organoids. The operational methodology provided ensures uniform and reproducible results, affording the means for rigorous examination of static MF effects. Thus, this protocol is a valuable resource for investigators seeking to explore the intricate interplay between MFs and living organisms. Key features • A comprehensive roadmap, suitable for undergraduate to advanced researchers, to construct an apparatus for in vitro and in vivo experiments within uniform static magnetic fields. • Designed to fit inside standard incubators to accommodate specific environmental conditions, such as with cell culture, in addition to stand-alone operation at room temperature. • Requires two DC power supplies and 3D printer access for the Helmholtz coils, Plexiglass and mu-metal foil for the partition, and a milli/Gaussmeter for calibration. • Requires ordering a custom mu-metal shell from a commercial resource (using provided schematics), where lead times for delivery can vary from 2 to 4 months., Competing Interests: Competing interestsThe authors confirm that there are no competing interests., (©Copyright : © 2024 The Authors; This is an open access article under the CC BY-NC license.)
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- 2024
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54. Immune System and Mind-Body Medicine: An Overview
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Calvillo, Laura, Parati, Gianfranco, Govoni, Stefano, editor, Politi, Pierluigi, editor, and Vanoli, Emilio, editor
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- 2020
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55. A Survey of Evolutionary Games in Biology
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Kastampolidou, Kalliopi, Andronikos, Theodore, Crusio, Wim E., Series Editor, Lambris, John D., Series Editor, Radeke, Heinfried H., Series Editor, Rezaei, Nima, Series Editor, and Vlamos, Panayiotis, editor
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- 2020
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56. Proton Quantum Tunneling: Influence and Relevance to Acidosis-Induced Cardiac Arrhythmias/Cardiac Arrest
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Omar Ababneh, Abdallah Barjas Qaswal, Ahmad Alelaumi, Lubna Khreesha, Mujahed Almomani, Majdi Khrais, Oweiss Khrais, Ahmad Suleihat, Shahed Mutleq, Yazan Al-olaimat, and Sager Nawafleh
- Subjects
quantum tunneling ,proton ,acidosis ,quantum biology ,quantum conductance ,voltage-gated channels ,Physiology ,QP1-981 - Abstract
Acidosis and its associated pathologies predispose patients to develop cardiac arrhythmias and even cardiac arrest. These arrhythmias are assumed to be the result of membrane depolarization, however, the exact mechanism of depolarization during acidosis is not well defined. In our study, the model of quantum tunneling of protons is used to explain the membrane depolarization that occurs during acidosis. It is found that protons can tunnel through closed activation and inactivation gates of voltage-gated sodium channels Nav1.5 that are present in the membrane of cardiac cells. The quantum tunneling of protons results in quantum conductance, which is evaluated to assess its effect on membrane potential. The quantum conductance of extracellular protons is higher than that of intracellular protons. This predicts an inward quantum current of protons through the closed sodium channels. Additionally, the values of quantum conductance are influential and can depolarize the membrane potential according to the quantum version of the GHK equation. The quantum mechanism of depolarization is distinct from other mechanisms because the quantum model suggests that protons can directly depolarize the membrane potential, and not only through indirect effects as proposed by other mechanisms in the literature. Understanding the pathophysiology of arrhythmias mediated by depolarization during acidosis is crucial to treat and control them and to improve the overall clinical outcomes of patients.
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- 2021
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57. Chronobiology Meets Quantum Biology: A New Paradigm Overlooking the Horizon?
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Mazzoccoli, Gianluigi
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QUANTUM biochemistry ,VISIBLE spectra ,CHRONOBIOLOGY ,PHENOMENOLOGICAL biology ,BIOLOGICAL systems - Abstract
Biological processes and physiological functions in living beings are featured by oscillations with a period of about 24 h (circadian) or cycle at the second and third harmonic (ultradian) of the basic frequency, driven by the biological clock. This molecular mechanism, common to all kingdoms of life, comprising animals, plants, fungi, bacteria, and protists, represents an undoubted adaptive advantage allowing anticipation of predictable changes in the environmental niche or of the interior milieu. Biological rhythms are the field of study of Chronobiology. In the last decade, growing evidence hints that molecular platforms holding up non-trivial quantum phenomena, including entanglement, coherence, superposition and tunnelling, bona fide evolved in biosystems. Quantum effects have been mainly implicated in processes related to electromagnetic radiation in the spectrum of visible light and ultraviolet rays, such as photosynthesis, photoreception, magnetoreception, DNA mutation, and not light related such as mitochondrial respiration and enzymatic activity. Quantum effects in biological systems are the field of study of Quantum Biology. Rhythmic changes at the level of gene expression, as well as protein quantity and subcellular distribution, confer temporal features to the molecular platform hosting electrochemical processes and non-trivial quantum phenomena. Precisely, a huge amount of molecules plying scaffold to quantum effects show rhythmic level fluctuations and this biophysical model implies that timescales of biomolecular dynamics could impinge on quantum mechanics biofunctional role. The study of quantum phenomena in biological cycles proposes a profitable "entanglement" between the areas of interest of these seemingly distant scientific disciplines to enlighten functional roles for quantum effects in rhythmic biosystems. [ABSTRACT FROM AUTHOR]
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- 2022
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58. Biology: Motion is Function.
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Koch, Lauren Gerard and Britton, Steven L
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SECOND law of thermodynamics , *RAYLEIGH-Benard convection , *NONEQUILIBRIUM thermodynamics , *ENERGY transfer , *AEROBIC metabolism , *PHYSICAL mobility - Abstract
In 1966 Francis Crick declared that: "The ultimate aim of the modern movement in biology is to explain all biology in terms of physics and chemistry." This motivated us to contemplate approaches that unify biology at a fundamental level. Exploration led us to consider the features of energy, entropy, and motion. Overall, it can be considered that motion of matter is the feature of life function. No motion. No function. In initial work we evaluated the hypothesis that the scope for biologic function is mediated mechanistically by a differential for energy transfer. Maximal treadmill running capacity served as a proxy for energy transfer. The span for capacity was estimated "biologically" by application of two-way artificial selection in rats for running capacity. Consistent with our "Energy Transfer Hypothesis" (ETH), low physical health and dysfunction segregated with low running capacity and high physical health and function segregated with high running capacity. The high energy yield of aerobic metabolism is also consonant with the ETH; that is, amongst the elements of the universe, oxygen is second only to fluorine in electronegativity. Although we deem these energy findings possibly correct, they are based on correlation and do not illuminate function via fundamental principles. For consideration of life, Entropy (2nd Law of thermodynamics) can be viewed as an open system that exchanges energy with the universe operating via nonequilibrium thermodynamics. The Principle of Maximal Entropy Production (MEP) states that: If a source of free energy is present, complex systems can intercept the free energy flow, and self-organize to enhance entropy production. The development of Benard convection cells in a water heat gradient demonstrate simplistic operation of MEP. A direct step forward would be to explain the mechanism of the obligatory motion of molecules for life function. Motion may be mediated by operation of "action at a distance" for molecules as considered by the Einstein-Podolsky-Rosen Paradox and confirmed by JS Bell. Magnetism, electricity, and gravity are also examples of action at a distance. We propose that some variant of "action at a distance" as directed by the property of Maximal Entropy Production (MEP) underwrites biologic motion. [ABSTRACT FROM AUTHOR]
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- 2022
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59. A novel bioinspired quantum photocell based on GaN quantum dots.
- Author
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Poonia, Vishvendra Singh
- Abstract
The efficiency of classical photocells is restricted by Shockley–Queisser limit and radiative recombination is one of the key contributors in efficiency degradation. Recent experiments on photosynthetic apparatus of plants and bacteria have suggested that these systems can overcome this limitation by exploiting excitonic quantum coherence. In photosynthetic apparatus, solar photons create excitons in the pigment protein molecules. These excitons are then transferred to the reaction centre where charge separation takes place. These processes – excitonic generation and subsequent charge separation – are extremely efficient with almost unity efficiency and avoid efficiency degradation due to radiative recombination. Taking a cue from this biophysical process, we propose a GaN quantum dot-based quantum photocell that emulates the photosynthetic reaction centre. The proposed photocell uses delocalised excitons to exhibit efficiency larger than its classical counterpart. This further suggests that highly efficient quantum biological processes can give important pointers for developing energy harvesting quantum technologies. [ABSTRACT FROM AUTHOR]
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- 2022
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60. Quantum Biology Research Meets Pathophysiology and Therapeutic Mechanisms: A Biomedical Perspective.
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Calvillo, Laura, Redaelli, Veronica, Ludwig, Nicola, Qaswal, Abdallah Barjas, Ghidoni, Alice, Faini, Andrea, Rosa, Debora, Lombardi, Carolina, Pengo, Martino, Bossolasco, Patrizia, Silani, Vincenzo, and Parati, Gianfranco
- Subjects
QUANTUM biochemistry ,TUBULINS ,PATHOLOGICAL physiology ,AUTONOMIC nervous system ,SLEEP apnea syndromes ,ELECTROMAGNETIC fields - Abstract
The recent advances of quantum biology suggest a potential role in biomedical research. Studies related to electromagnetic fields, proton pumping in mitochondrial respiratory chain, quantum theory of T-cell receptor (TCR)-degeneracy, theories on biophotons, pyrophosphates or tubulin as possible carriers for neural information, and quantum properties of ions and protons, might be useful for understanding mechanisms of some serious immune, cardiovascular, and neural pathologies for which classic biomedical research, based on biochemical approach, is struggling to find new therapeutic strategies. A breakthrough in medical knowledge is therefore needed in order to improve the understanding of the complex interactions among various systems and organs typical of such pathologies. In particular, problems related to immune system over-activation, to the role of autonomic nervous system (ANS) dysfunction in the obstructive sleep apnea (OSA) syndrome, to the clinical consequences of ion channels dysfunction and inherited cardiac diseases, could benefit from the new perspective provided by quantum biology advancement. Overall, quantum biology might provide a promising biophysical theoretic system, on which to base pathophysiology understanding and hopefully therapeutic strategies. With the present work, authors hope to open a constructive and multidisciplinary debate on this important topic. [ABSTRACT FROM AUTHOR]
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- 2022
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61. Quantum Mechanical Aspects in the Pathophysiology of Neuropathic Pain.
- Author
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Nawafleh, Sager, Qaswal, Abdallah Barjas, Alali, Obada, Zayed, Fuad Mohammed, Al-Azzam, Ahmed Mahmoud, Al-Kharouf, Khaled, Ali, Mo'ath Bani, Albliwi, Moath Ahmad, Al-Hamarsheh, Rawan, Iswaid, Mohammad, Albanna, Ahmad, Enjadat, Ahmad, Al-Adwan, Mohammad Abu Orabi, Dibbeh, Khaled, Shareah, Ez-Aldeen Abu, Hamdan, Anas, and Suleiman, Aiman
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- *
NEURALGIA , *QUANTUM tunneling , *ACTION potentials , *PATHOLOGICAL physiology , *SODIUM ions - Abstract
Neuropathic pain is a challenging complaint for patients and clinicians since there are no effective agents available to get satisfactory outcomes even though the pharmacological agents target reasonable pathophysiological mechanisms. This may indicate that other aspects in these mechanisms should be unveiled to comprehend the pathogenesis of neuropathic pain and thus find more effective treatments. Therefore, in the present study, several mechanisms are chosen to be reconsidered in the pathophysiology of neuropathic pain from a quantum mechanical perspective. The mathematical model of the ions quantum tunneling model is used to provide quantum aspects in the pathophysiology of neuropathic pain. Three major pathophysiological mechanisms are revisited in the context of the quantum tunneling model. These include: (1) the depolarized membrane potential of neurons; (2) the cross-talk or the ephaptic coupling between the neurons; and (3) the spontaneous neuronal activity and the emergence of ectopic action potentials. We will show mathematically that the quantum tunneling model can predict the occurrence of neuronal membrane depolarization attributed to the quantum tunneling current of sodium ions. Moreover, the probability of inducing an ectopic action potential in the axons of neurons will be calculated and will be shown to be significant and influential. These ectopic action potentials are generated due to the formation of quantum synapses which are assumed to be the mechanism behind the ephaptic transmission. Furthermore, the spontaneous neuronal activity and the emergence of ectopic action potentials independently from any adjacent stimulated neurons are predicted to occur according to the quantum tunneling model. All these quantum mechanical aspects contribute to the overall hyperexcitability of the neurons and to the pathogenesis of neuropathic pain. Additionally, providing a new perspective in the pathophysiology of neuropathic pain may improve our understanding of how the neuropathic pain is generated and maintained and may offer new effective agents that can improve the overall clinical outcomes of the patients. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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62. Chronobiology Meets Quantum Biology: A New Paradigm Overlooking the Horizon?
- Author
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Gianluigi Mazzoccoli
- Subjects
chronobiology ,quantum biology ,quantum mechanics ,entanglement ,tunneling ,coherence ,Physiology ,QP1-981 - Abstract
Biological processes and physiological functions in living beings are featured by oscillations with a period of about 24 h (circadian) or cycle at the second and third harmonic (ultradian) of the basic frequency, driven by the biological clock. This molecular mechanism, common to all kingdoms of life, comprising animals, plants, fungi, bacteria, and protists, represents an undoubted adaptive advantage allowing anticipation of predictable changes in the environmental niche or of the interior milieu. Biological rhythms are the field of study of Chronobiology. In the last decade, growing evidence hints that molecular platforms holding up non-trivial quantum phenomena, including entanglement, coherence, superposition and tunnelling, bona fide evolved in biosystems. Quantum effects have been mainly implicated in processes related to electromagnetic radiation in the spectrum of visible light and ultraviolet rays, such as photosynthesis, photoreception, magnetoreception, DNA mutation, and not light related such as mitochondrial respiration and enzymatic activity. Quantum effects in biological systems are the field of study of Quantum Biology. Rhythmic changes at the level of gene expression, as well as protein quantity and subcellular distribution, confer temporal features to the molecular platform hosting electrochemical processes and non-trivial quantum phenomena. Precisely, a huge amount of molecules plying scaffold to quantum effects show rhythmic level fluctuations and this biophysical model implies that timescales of biomolecular dynamics could impinge on quantum mechanics biofunctional role. The study of quantum phenomena in biological cycles proposes a profitable “entanglement” between the areas of interest of these seemingly distant scientific disciplines to enlighten functional roles for quantum effects in rhythmic biosystems.
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- 2022
- Full Text
- View/download PDF
63. The Quantum Tunneling of Ions Model Can Explain the Pathophysiology of Tinnitus.
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Al-Rawashdeh, Baeth M, Qaswal, Abdallah Barjas, Suleiman, Aiman, Zayed, Fuad Mohammed, Al-Rawashdeh, S. M., Tawalbeh, Mohamed, Khreesha, Lubna, Alzubaidi, Ayham, Al-Zubidi, Enas, Ghala, Zuhir, Almasri, Ahmad, Yasein, Mohammed, Ojjoh, Khaled, Alraiqib, Ahmad, Iswaid, Mohammad, Emar, Murad, Haimour, Shahed, Saifan, Ala', and Mahameed, Zaid
- Subjects
- *
QUANTUM tunneling , *AUDITORY pathways , *ACTION potentials , *AUDITORY neurons , *HAIR cells - Abstract
Tinnitus is a well-known pathological entity in clinical practice. However, the pathophysiological mechanisms behind tinnitus seem to be elusive and cannot provide a comprehensive understanding of its pathogenesis and clinical manifestations. Hence, in the present study, we explore the mathematical model of ions' quantum tunneling to propose an original pathophysiological mechanism for the sensation of tinnitus. The present model focuses on two major aspects: The first aspect is the ability of ions, including sodium, potassium, and calcium, to depolarize the membrane potential of inner hair cells and the neurons of the auditory pathway. This membrane depolarization is induced via the quantum tunneling of ions through closed voltage-gated channels. The state of membrane depolarization can be a state of hyper-excitability or hypo-excitability, depending on the degree of depolarization. Both of these states aid in understanding the pathophysiology of tinnitus. The second aspect is the quantum tunneling signals between the demyelinated neurons of the auditory pathway. These signals are mediated via the quantum tunneling of potassium ions, which exit to the extracellular fluid during an action potential event. These quantum signals can be viewed as a "quantum synapse" between neurons. The formation of quantum synapses results in hyper-excitability among the demyelinated neurons of the auditory pathway. Both of these aspects augment and amplify the electrical signals in the auditory pathway and result in a loss of the spatiotemporal fidelity of sound signals going to the brain centers. The brain interprets this hyper-excitability and loss of spatiotemporal fidelity as tinnitus. Herein, we show mathematically that the quantum tunneling of ions can depolarize the membrane potential of the inner hair cells and neurons of the auditory pathway. Moreover, we calculate the probability of action potential induction in the neurons of the auditory pathway generated by the quantum tunneling signals of potassium ions. [ABSTRACT FROM AUTHOR]
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- 2022
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64. Quantum Neurobiology.
- Author
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Swan, Melanie, dos Santos, Renato P., and Witte, Franke
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MEDICAL informatics ,NEUROBIOLOGY ,QUANTUM information science ,LARGE-scale brain networks ,POSITRON emission tomography ,PROTEIN folding - Abstract
Quantum neurobiology is concerned with potential quantum effects operating in the brain and the application of quantum information science to neuroscience problems, the latter of which is the main focus of the current paper. The human brain is fundamentally a multiscalar problem, with complex behavior spanning nine orders of magnitude-scale tiers from the atomic and cellular level to brain networks and the central nervous system. In this review, we discuss a new generation of bio-inspired quantum technologies in the emerging field of quantum neurobiology and present a novel physics-inspired theory of neural signaling (AdS/Brain (anti-de Sitter space)). Three tiers of quantum information science-directed neurobiology applications can be identified. First are those that interpret empirical data from neural imaging modalities (EEG, MRI, CT, PET scans), protein folding, and genomics with wavefunctions and quantum machine learning. Second are those that develop neural dynamics as a broad approach to quantum neurobiology, consisting of superpositioned data modeling evaluated with quantum probability, neural field theories, filamentary signaling, and quantum nanoscience. Third is neuroscience physics interpretations of foundational physics findings in the context of neurobiology. The benefit of this work is the possibility of an improved understanding of the resolution of neuropathologies such as Alzheimer's disease. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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65. Thermodynamics and Inflammation: Insights into Quantum Biology and Ageing.
- Author
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Nunn, Alistair Victor William, Guy, Geoffrey William, and Bell, Jimmy David
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QUANTUM biochemistry ,THERMODYNAMICS ,INFLAMMATION ,QUANTUM mechanics ,HORMESIS ,AGING - Abstract
Inflammation as a biological concept has been around a long time and derives from the Latin "to set on fire" and refers to the redness and heat, and usually swelling, which accompanies injury and infection. Chronic inflammation is also associated with ageing and is described by the term "inflammaging". Likewise, the biological concept of hormesis, in the guise of what "does not kill you, makes you stronger", has long been recognized, but in contrast, seems to have anti-inflammatory and age-slowing characteristics. As both phenomena act to restore homeostasis, they may share some common underlying principles. Thermodynamics describes the relationship between heat and energy, but is also intimately related to quantum mechanics. Life can be viewed as a series of self-renewing dissipative structures existing far from equilibrium as vortexes of "negentropy" that ages and dies; but, through reproduction and speciation, new robust structures are created, enabling life to adapt and continue in response to ever changing environments. In short, life can be viewed as a natural consequence of thermodynamics to dissipate energy to restore equilibrium; each component of this system is replaceable. However, at the molecular level, there is perhaps a deeper question: is life dependent on, or has it enhanced, quantum effects in space and time beyond those normally expected at the atomistic scale and temperatures that life operates at? There is some evidence it has. Certainly, the dissipative adaptive mechanism described by thermodynamics is now being extended into the quantum realm. Fascinating though this topic is, does exploring the relationship between quantum mechanics, thermodynamics, and biology give us a greater insight into ageing and, thus, medicine? It could be said that hormesis and inflammation are expressions of thermodynamic and quantum principles that control ageing via natural selection that could operate at all scales of life. Inflammation could be viewed as a mechanism to remove inefficient systems in response to stress to enable rebuilding of more functional dissipative structures, and hormesis as the process describing the ability to adapt; underlying this is the manipulation of fundamental quantum principles. Defining what "quantum biological normality" is has been a long-term problem, but perhaps we do not need to, as it is simply an expression of one end of the normal quantum mechanical spectrum, implying that biology could inform us as to how we can define the quantum world. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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66. Primo Vascular System: Before the Past, Bizarre Present and Peek After the Future.
- Author
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Stefanov, Miroslav
- Subjects
BLOOD vessels ,DNA ,SERIAL publications ,BIOELECTROMAGNETISM ,QI (Chinese philosophy) ,BIOLOGY ,LIFE ,ACUPUNCTURE points ,ASIAN medicine ,INFORMATION science - Abstract
Introduction: Is Primo Vascular System (PVS) a paradox? Finding the connection between PVS as a carrier of information and the body's reactions at the micro and macro levels will be the starting point in understanding the meaning of life as such. Before the past of PVS knowledge: The initial phase of medicine in all cultures is reduced to the transfer of specific energy by special pathways throughout the body! This is the case in China, India, Japan, Korea, Tibet, etc. Undoubtedly, the five articles by B. H. Kim published in the early 1960s are considered to be the past of PVS. Strange present: PVS studies after 2002 are accepted as a present. Most of the articles on the topic are in journals with editors-in-chief originating and/or accepting the achievements of Eastern medicine. Is the science of PVS local since its research is in journals that publish mainly articles on Eastern medicine? Why few of the articles concerning PVS are in Western medicine journals? PVS: after the future or some conclusions and proposals: All substances, objects, biological objects generate a weak electromagnetic radiation typical for each of them which is a passport of the information. PVS has all the data to be the main carrier of information. Information medicine and Quantum Biology can serve as a basis for medicine and biomedical sciences, and it should explain the processes that exist for the change of DNA and organisms in general, in accordance with and in response to external causes and internal changes. [ABSTRACT FROM AUTHOR]
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- 2022
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67. How to Approach Śūnyatā as the Quantum Reality Through Biological Consciousness?
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Singh, Bal Ram and Bhatt, Siddheshwar Rameshwar, editor
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- 2019
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68. Quantum Biology: An Update and Perspective
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Youngchan Kim, Federico Bertagna, Edeline M. D’Souza, Derren J. Heyes, Linus O. Johannissen, Eveliny T. Nery, Antonio Pantelias, Alejandro Sanchez-Pedreño Jimenez, Louie Slocombe, Michael G. Spencer, Jim Al-Khalili, Gregory S. Engel, Sam Hay, Suzanne M. Hingley-Wilson, Kamalan Jeevaratnam, Alex R. Jones, Daniel R. Kattnig, Rebecca Lewis, Marco Sacchi, Nigel S. Scrutton, S. Ravi P. Silva, and Johnjoe McFadden
- Subjects
quantum biology ,non-trivial quantum effects in biology ,quantum tunnelling in enzyme-catalysed reactions ,photosynthesis ,synthetic light harvesting system ,ion channel ,Physics ,QC1-999 - Abstract
Understanding the rules of life is one of the most important scientific endeavours and has revolutionised both biology and biotechnology. Remarkable advances in observation techniques allow us to investigate a broad range of complex and dynamic biological processes in which living systems could exploit quantum behaviour to enhance and regulate biological functions. Recent evidence suggests that these non-trivial quantum mechanical effects may play a crucial role in maintaining the non-equilibrium state of biomolecular systems. Quantum biology is the study of such quantum aspects of living systems. In this review, we summarise the latest progress in quantum biology, including the areas of enzyme-catalysed reactions, photosynthesis, spin-dependent reactions, DNA, fluorescent proteins, and ion channels. Many of these results are expected to be fundamental building blocks towards understanding the rules of life.
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- 2021
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69. From quantum chemistry to quantum biology: a path toward consciousness
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Jack A. Tuszynski
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quantum physics ,quantum biology ,quantum metabolism ,consciousness ,Neurosciences. Biological psychiatry. Neuropsychiatry ,RC321-571 - Abstract
This paper presents a historical overview of quantum physics methodology's development and application to various science fields beyond physics, especially biology and consciousness. Following a successful interpretation of several early 20th century experiments, quantum physics gradually provided a conceptual framework for molecular bonds via quantum chemistry. In recent years individual biological phenomena such as photosynthesis and bird navigation have been experimentally and theoretically analyzed using quantum methods, building conceptual foundations for quantum physics' entry into biology. Quantum concepts have also been recently employed to explain physiology's allometric scaling laws by introducing quantum metabolism theory. In the second part of this work, we discuss how quantum physics may also be pivotal to our understanding of consciousness, which has been touted by some researchers as the last frontier of modern science. Others believe that consciousness does not belong within the realm of science at all. Several hypotheses, especially the Orch OR theory, have been suggested over the past two decades to introduce a scientific basis to consciousness theory. We discuss the merits and potential extensions of these approaches.
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- 2020
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70. On the Mechanistic Perceptions of Consciousness: From Quantum Mechanics to Consciousness and Free Will and from David Bohm to Benjamin Libet.
- Author
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Franco, Rafael
- Subjects
- *
HEISENBERG model , *LATTICE models (Statistical physics) , *FERROMAGNETISM , *AWARENESS , *COGNITION - Abstract
The article discusses Heisenberg uncertainty principle, for which quantum mechanics establish some limits. Topics include the potential of certain types of biological assays for advancing the understanding of consciousness; experiment to demonstrate how brain-mind interactions work requires humans and is possible, and question that arises whether studies using animal models can be of interest to what only humans can have.
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- 2022
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71. Redox conditions correlated with vibronic coupling modulate quantum beats in photosynthetic pigment-protein complexes.
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Higgins, Jacob S., Allodi, Marco A., Lloyd, Lawson T., Otto, John P., Sohail, Sara H., Saer, Rafael G., Wood, Ryan E., Massey, Sara C., Po-Chieh Ting, Blankenship, Robert E., and Engel, Gregory S.
- Subjects
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VIBRONIC coupling , *ENERGY transfer , *QUANTUM coherence , *SULFUR bacteria , *OXIDATION-reduction reaction , *COMMERCIAL products - Abstract
Quantum coherences, observed as time-dependent beats in ultrafast spectroscopic experiments, arise when light-matter interactions prepare systems in superpositions of states with differing energy and fixed phase across the ensemble. Such coherences have been observed in photosynthetic systems following ultrafast laser excitation, but what these coherences imply about the underlying energy transfer dynamics remains subject to debate. Recent work showed that redox conditions tune vibronic coupling in the Fenna-Matthews-Olson (FMO) pigment-protein complex in green sulfur bacteria, raising the question of whether redox conditions may also affect the long-lived (>100 fs) quantum coherences observed in this complex. In this work, we perform ultrafast twodimensional electronic spectroscopy measurements on the FMO complex under both oxidizing and reducing conditions. We observe that many excited-state coherences are exclusively present in reducing conditions and are absent or attenuated in oxidizing conditions. Reducing conditions mimic the natural conditions of the complex more closely. Further, the presence of these coherences correlates with the vibronic coupling that produces faster, more efficient energy transfer through the complex under reducing conditions. The growth of coherences across the waiting time and the number of beating frequencies across hundreds of wavenumbers in the power spectra suggest that the beats are excitedstate coherences with a mostly vibrational character whose phase relationship is maintained through the energy transfer process. Our results suggest that excitonic energy transfer proceeds through a coherent mechanism in this complex and that the coherences may provide a tool to disentangle coherent relaxation from energy transfer driven by stochastic environmental fluctuations. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
72. Proton Quantum Tunneling: Influence and Relevance to Acidosis-Induced Cardiac Arrhythmias/Cardiac Arrest.
- Author
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Ababneh, Omar, Qaswal, Abdallah Barjas, Alelaumi, Ahmad, Khreesha, Lubna, Almomani, Mujahed, Khrais, Majdi, Khrais, Oweiss, Suleihat, Ahmad, Mutleq, Shahed, Al-olaimat, Yazan, and Nawafleh, Sager
- Subjects
- *
QUANTUM tunneling , *ARRHYTHMIA , *CARDIAC arrest , *MEMBRANE potential , *SODIUM channels , *HEART cells - Abstract
Acidosis and its associated pathologies predispose patients to develop cardiac arrhythmias and even cardiac arrest. These arrhythmias are assumed to be the result of membrane depolarization, however, the exact mechanism of depolarization during acidosis is not well defined. In our study, the model of quantum tunneling of protons is used to explain the membrane depolarization that occurs during acidosis. It is found that protons can tunnel through closed activation and inactivation gates of voltage-gated sodium channels Nav1.5 that are present in the membrane of cardiac cells. The quantum tunneling of protons results in quantum conductance, which is evaluated to assess its effect on membrane potential. The quantum conductance of extracellular protons is higher than that of intracellular protons. This predicts an inward quantum current of protons through the closed sodium channels. Additionally, the values of quantum conductance are influential and can depolarize the membrane potential according to the quantum version of the GHK equation. The quantum mechanism of depolarization is distinct from other mechanisms because the quantum model suggests that protons can directly depolarize the membrane potential, and not only through indirect effects as proposed by other mechanisms in the literature. Understanding the pathophysiology of arrhythmias mediated by depolarization during acidosis is crucial to treat and control them and to improve the overall clinical outcomes of patients. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
73. The Origin Paradox: How Could Life Emerge from Nonlife?
- Author
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Soteropoulos, Ion, Smith, William S., Series Editor, Verducci, Daniela, Series Editor, and Smith, Jadwiga S., editor
- Published
- 2018
- Full Text
- View/download PDF
74. Quantum Pancomputationalism and Statistical Data Science: From Symbolic to Statistical AI, and to Quantum AI
- Author
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Maruyama, Yoshihiro, Magnani, Lorenzo, Series Editor, and Müller, Vincent C., editor
- Published
- 2018
- Full Text
- View/download PDF
75. Mathematical Model of Quorum Sensing and Biofilm
- Author
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Majumdar, Sarangam, Roy, Sisir, and Pallaval Veera Bramhachari, editor
- Published
- 2018
- Full Text
- View/download PDF
76. On the Mechanistic Perceptions of Consciousness: From Quantum Mechanics to Consciousness and Free Will and from David Bohm to Benjamin Libet
- Author
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Rafael Franco
- Subjects
awareness ,cerebral field ,consciousness ,free will ,quantum biology ,quantum chemistry ,Neurosciences. Biological psychiatry. Neuropsychiatry ,RC321-571 - Published
- 2022
- Full Text
- View/download PDF
77. Energy transport in open quantum systems
- Author
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Pollock, Felix Alexander and Vedral, Vlatko
- Subjects
530.12 ,Theoretical physics ,Open quantum systems ,quantum biology - Abstract
This thesis is concerned with modelling the dynamics of open quantum systems in several different contexts. Of principal interest is the manner in which the environment can modify, or even dominate, a system’s quantum behaviour in order to facilitate the transport of energetic excitations. In the first research chapter, a time-local, non-Markovian quantum master equation is derived in a variationally defined reference frame, for networks of two-level systems coupled to bosonic environments. The predictions of this master equation are then compared with those derived using both weak-coupling and polaron approximations. The variational master equation is found to agree with these standard approaches in their regimes of validity, whilst interpolating between them in intermediate parameter regimes. The second research chapter focusses on the dynamics of a superconducting double quantum dot embedded in a resonant circuit. The device is considered in a regime where the ground state consists of a coherent spatial superposition of a single Cooper pair, which can be excited by a variety of interactions with the environment. The relevant transition rates are calculated and the processes responsible are identified. A numerical simulation of the system is then used to explain experimental data, and show that for certain parameters a significant fraction of excitations occur via absorption of photons from the environment. The final chapter considers a model for an olfactory receptor, in which odorant molecules are recognised by their vibrational modes. Electron transfer occurs in the receptor, dependent on the presence of a vibrational mode of the right frequency. A quantum master equation for the system is derived, and the resulting dynamics is compared to earlier semi-classical treatments. The behaviour of the receptor is found to be sensitive not only to the frequency of the vibrational mode, but also to the character of the surrounding environment. Increased dissipation on the odorant mode, as well as the presence of higher frequencies in the environment is found to improve the frequency resolution of the receptor.
- Published
- 2014
78. Quantum Speedup for Protein Structure Prediction.
- Author
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Wong, Renata and Chang, Weng-Long
- Abstract
Protein structure prediction (PSP) predicts the native conformation for a given protein sequence. Classically, the problem has been shown to belong to the NP-complete complexity class. Its applications range from physics, through bioinformatics to medicine and quantum biology. It is possible however to speed it up with quantum computational methods, as we show in this paper. Here we develop a fast quantum algorithm for PSP in three-dimensional hydrophobic-hydrophilic model on body-centered cubic lattice with quadratic speedup over its classical counterparts. Given a protein sequence of ${n}$ amino acids, our algorithm reduces the temporal and spatial complexities to, respectively, ${O}\left({{2}^{\frac {n}{{2}}}}\right)$ and ${O}({n}^{{2}} \log {n})$. With respect to oracle-related quantum algorithms for the NP-complete problems, we identify our algorithm as optimal. To justify the feasibility of the proposed algorithm we successfully solve the problem on IBM quantum simulator involving 21 and 25 qubits. We confirm the experimentally obtained high probability of success in finding the desired conformation by calculating the theoretical probability estimations. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
79. The avian compass can be sensitive even without sustained electron spin coherence.
- Author
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Jain, Rakshit, Poonia, Vishvendra S., Saha, Kasturi, Saha, Dipankar, and Ganguly, Swaroop
- Subjects
- *
HYPERFINE interactions , *QUANTUM biochemistry , *QUANTUM coherence , *ELECTRON spin - Abstract
Theoretical studies indicating the presence of long-lived coherence in the radical pair system have engendered questions about its utilitarian role in the avian compass. In this paper, we investigate the role of electron spin coherence in a multinuclear radical pair system including its impact on compass sensitivity. We find that sustenance of long-lived electron spin coherence is unlikely in a multinuclear hyperfine environment. After probing the role of the hyperfine interactions in the compass, we affirm the hyperfine anisotropy to be an essential parameter for the necessary sensitivity required for the compass action. Thereby, we identify a parameter regime where the compass would exhibit good sensitivity even without sustained electron spin coherence. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
80. The Possibility of Quantum Medicine in Cancer Research: A Review.
- Author
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Faramarzpour, Mahsa, Ghaderinia, Mohammadreza, Abadijoo, Hamed, and Aghababa, Hossein
- Subjects
- *
LITERATURE reviews , *QUANTUM biochemistry , *PHENOMENOLOGICAL biology , *MEDICAL research , *CANCER research - Abstract
There is no doubt that quantum mechanics has become one of the building blocks of our physical world today. It is one of the most rapidly growing fields of science that can potentially change every aspect of our life. Quantum biology is one of the most essential parts of this era which can be considered as a game-changer in medicine especially in the field of cancer. Despite quantum biology having gained more attention during the last decades, there are still so many unanswered questions concerning cancer biology and so many unpaved roads in this regard. This review paper is an effort to answer the question of how biological phenomena such as cancer can be described through the quantum mechanical framework. In other words, is there a correlation between cancer biology and quantum mechanics, and how? This literature review paper reports on the recently published researches based on the principles of quantum physics with focus on cancer biology and metabolism. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
81. Quantum Mechanical Aspects in the Pathophysiology of Neuropathic Pain
- Author
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Sager Nawafleh, Abdallah Barjas Qaswal, Obada Alali, Fuad Mohammed Zayed, Ahmed Mahmoud Al-Azzam, Khaled Al-Kharouf, Mo’ath Bani Ali, Moath Ahmad Albliwi, Rawan Al-Hamarsheh, Mohammad Iswaid, Ahmad Albanna, Ahmad Enjadat, Mohammad Abu Orabi Al-Adwan, Khaled Dibbeh, Ez-Aldeen Abu Shareah, Anas Hamdan, and Aiman Suleiman
- Subjects
neuropathic pain ,quantum tunneling ,ion channels ,quantum biology ,quantum medicine ,quantum conductance ,Neurosciences. Biological psychiatry. Neuropsychiatry ,RC321-571 - Abstract
Neuropathic pain is a challenging complaint for patients and clinicians since there are no effective agents available to get satisfactory outcomes even though the pharmacological agents target reasonable pathophysiological mechanisms. This may indicate that other aspects in these mechanisms should be unveiled to comprehend the pathogenesis of neuropathic pain and thus find more effective treatments. Therefore, in the present study, several mechanisms are chosen to be reconsidered in the pathophysiology of neuropathic pain from a quantum mechanical perspective. The mathematical model of the ions quantum tunneling model is used to provide quantum aspects in the pathophysiology of neuropathic pain. Three major pathophysiological mechanisms are revisited in the context of the quantum tunneling model. These include: (1) the depolarized membrane potential of neurons; (2) the cross-talk or the ephaptic coupling between the neurons; and (3) the spontaneous neuronal activity and the emergence of ectopic action potentials. We will show mathematically that the quantum tunneling model can predict the occurrence of neuronal membrane depolarization attributed to the quantum tunneling current of sodium ions. Moreover, the probability of inducing an ectopic action potential in the axons of neurons will be calculated and will be shown to be significant and influential. These ectopic action potentials are generated due to the formation of quantum synapses which are assumed to be the mechanism behind the ephaptic transmission. Furthermore, the spontaneous neuronal activity and the emergence of ectopic action potentials independently from any adjacent stimulated neurons are predicted to occur according to the quantum tunneling model. All these quantum mechanical aspects contribute to the overall hyperexcitability of the neurons and to the pathogenesis of neuropathic pain. Additionally, providing a new perspective in the pathophysiology of neuropathic pain may improve our understanding of how the neuropathic pain is generated and maintained and may offer new effective agents that can improve the overall clinical outcomes of the patients.
- Published
- 2022
- Full Text
- View/download PDF
82. How Can the Green Sulfur Bacteria in the Depths of the Black Sea Use Quantum Computing for Light Harvesting?
- Author
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Drakova, Deiana, Doyen, Gerold, Maruani, Jean, Series editor, Wilson, Stephen, Series editor, Tadjer, Alia, editor, Pavlov, Rossen, editor, Brändas, Erkki J., editor, and Delgado-Barrio, Gerardo, editor
- Published
- 2017
- Full Text
- View/download PDF
83. OUTSTANDING ISSUES WITH ROBERT RUSSELL'S NIODA CONCERNING QUANTUM BIOLOGY AND THEISTIC EVOLUTION.
- Author
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Qureshi‐Hurst, Emily and Bennett, Christopher T.
- Abstract
Non‐Interventionist Objective Divine Action (NIODA), introduced by Robert John Russell, is a model of divine action drawing upon insights from quantum mechanics. It presents an intriguing and significant challenge to classical conceptions of divine action with far‐reaching consequences. When applying NIODA to theistic evolution, however, significant questions emerge that require attention. We identify and assess two sets of concerns. The first relates to quantum physics, particularly whether and how quantum occurrences influence mutations and evolution. We argue that the current empirical evidence is ambiguous in its support of the kinds of quantum action that Russell proposes, though emerging data from quantum biology look promising. The second set of concerns is metaphysical, especially concerning the problem of evil. NIODA gives Godextensive agency over evolution and genetics, which has adverse consequences for theodicy. We propose potential solutions to the problems highlighted in our article, both metaphysical and physical, to improve the viability of NIODA's application to theistic evolution. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
84. Mathematical Modeling of Ion Quantum Tunneling Reveals Novel Properties of Voltage-Gated Channels and Quantum Aspects of Their Pathophysiology in Excitability-Related Disorders.
- Author
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Qaswal, Abdallah Barjas, Ababneh, Omar, Khreesha, Lubna, Al-Ani, Abdallah, Suleihat, Ahmad, and Abbad, Mutaz
- Subjects
- *
QUANTUM tunneling , *CLASSICAL mechanics , *ACTION potentials , *QUANTUM mechanics , *PATHOLOGICAL physiology , *MEMBRANE potential , *QUANTUM gates - Abstract
Voltage-gated channels are crucial in action potential initiation and propagation and there are many diseases and disorders related to them. Additionally, the classical mechanics are the main mechanics used to describe the function of the voltage-gated channels and their related abnormalities. However, the quantum mechanics should be considered to unravel new aspects in the voltage-gated channels and resolve the problems and challenges that classical mechanics cannot solve. In the present study, the aim is to mathematically show that quantum mechanics can exhibit a powerful tendency to unveil novel electrical features in voltage-gated channels and be used as a promising tool to solve the problems and challenges in the pathophysiology of excitability-related diseases. The model of quantum tunneling of ions through the intracellular hydrophobic gate is used to evaluate the influence of membrane potential and gating free energy on the tunneling probability, single channel conductance, and quantum membrane conductance. This evaluation is mainly based on graphing the mathematical relationships between these variables. The obtained mathematical graphs showed that ions can achieve significant quantum membrane conductance, which can affect the resting membrane potential and the excitability of cells. In the present work, quantum mechanics reveals original electrical properties associated with voltage-gated channels and introduces new insights and implications into the pathophysiology of excitability- related disorders. In addition, the present work sets a mathematical and theoretical framework that can be utilized to conduct experimental studies in order to explore the quantum aspects of voltage-gated channels and the quantum bioelectrical property of biological membranes. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
85. Marine cyanobacteria tune energy transfer efficiency in their light‐harvesting antennae by modifying pigment coupling.
- Author
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Kolodny, Yuval, Zer, Hagit, Propper, Mor, Yochelis, Shira, Paltiel, Yossi, and Keren, Nir
- Subjects
- *
ENERGY transfer , *FLUORESCENCE resonance energy transfer , *CROSS-cultural studies , *BIOLOGICAL productivity , *CYANOBACTERIA - Abstract
Photosynthetic light harvesting is the first step in harnessing sunlight toward biological productivity. To operate efficiently under a broad and dynamic range of environmental conditions, organisms must tune the harvesting process according to the available irradiance. The marine cyanobacteria Synechococcus WH8102 species is well‐adapted to vertical mixing of the water column. By studying its responses to different light regimes, we identify a new photo‐acclimation strategy. Under low light, the phycobilisome (PBS) is bigger, with extended rods, increasing the absorption cross‐section. In contrast to what was reported in vascular plants and predicted by Forster resonance energy transfer (FRET) calculations, these longer rods transfer energy faster than in the phycobilisomes of cells acclimated to a higher light intensity. Comparison of cultures grown under different blue light intensities, using fluorescence lifetime and emission spectra dependence on temperature at the range of 4–200 K in vivo, indicates that the improved transfer arises from enhanced energetic coupling between the antenna rods' pigments. We suggest two physical models according to which the enhanced coupling strength results either from additional coupled pathways formed by rearranging rod packing or from the coupling becoming non‐classical. In both cases, the energy transfer would be more efficient than standard one‐dimensional FRET process. These findings suggest that coupling control can be a major factor in photosynthetic antenna acclimation to different light conditions. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
86. The Quantum Tunneling of Ions Model Can Explain the Pathophysiology of Tinnitus
- Author
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Baeth M Al-Rawashdeh, Abdallah Barjas Qaswal, Aiman Suleiman, Fuad Mohammed Zayed, S. M. Al-Rawashdeh, Mohamed Tawalbeh, Lubna Khreesha, Ayham Alzubaidi, Enas Al-Zubidi, Zuhir Ghala, Ahmad Almasri, Mohammed Yasein, Khaled Ojjoh, Ahmad Alraiqib, Mohammad Iswaid, Murad Emar, Shahed Haimour, Ala’ Saifan, and Zaid Mahameed
- Subjects
tinnitus ,quantum tunneling ,quantum biology ,inner hair cell ,quantum conductance ,voltage-gated channel ,Neurosciences. Biological psychiatry. Neuropsychiatry ,RC321-571 - Abstract
Tinnitus is a well-known pathological entity in clinical practice. However, the pathophysiological mechanisms behind tinnitus seem to be elusive and cannot provide a comprehensive understanding of its pathogenesis and clinical manifestations. Hence, in the present study, we explore the mathematical model of ions’ quantum tunneling to propose an original pathophysiological mechanism for the sensation of tinnitus. The present model focuses on two major aspects: The first aspect is the ability of ions, including sodium, potassium, and calcium, to depolarize the membrane potential of inner hair cells and the neurons of the auditory pathway. This membrane depolarization is induced via the quantum tunneling of ions through closed voltage-gated channels. The state of membrane depolarization can be a state of hyper-excitability or hypo-excitability, depending on the degree of depolarization. Both of these states aid in understanding the pathophysiology of tinnitus. The second aspect is the quantum tunneling signals between the demyelinated neurons of the auditory pathway. These signals are mediated via the quantum tunneling of potassium ions, which exit to the extracellular fluid during an action potential event. These quantum signals can be viewed as a “quantum synapse” between neurons. The formation of quantum synapses results in hyper-excitability among the demyelinated neurons of the auditory pathway. Both of these aspects augment and amplify the electrical signals in the auditory pathway and result in a loss of the spatiotemporal fidelity of sound signals going to the brain centers. The brain interprets this hyper-excitability and loss of spatiotemporal fidelity as tinnitus. Herein, we show mathematically that the quantum tunneling of ions can depolarize the membrane potential of the inner hair cells and neurons of the auditory pathway. Moreover, we calculate the probability of action potential induction in the neurons of the auditory pathway generated by the quantum tunneling signals of potassium ions.
- Published
- 2022
- Full Text
- View/download PDF
87. Cellular autofluorescence is magnetic field sensitive.
- Author
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Noboru Ikeya and Woodward, Jonathan R.
- Subjects
- *
MAGNETIC fields , *BIOFLUORESCENCE , *MAGNETIC field effects , *PHOTOINDUCED electron transfer , *OXIDATION-reduction reaction - Abstract
We demonstrate, by direct, single-cell imaging kinetic measurements, that endogenous autofluorescence in HeLa cells is sensitive to the application of external magnetic fields of 25 mT and less. We provide spectroscopic and mechanistic evidence that our findings can be explained in terms of magnetic field effects on photoinduced electron transfer reactions to flavins, through the radical pair mechanism. The observed magnetic field dependence is consistent with a triplet-born radical pair and a B1/2 value of 18.0 mT with a saturation value of 3.7%. [ABSTRACT FROM AUTHOR]
- Published
- 2021
- Full Text
- View/download PDF
88. Arabidopsis cryptochrome and Quantum Biology: new insights for plant science and crop improvement.
- Author
-
Pooam, Marootpong, El-Esawi, Mohamed, Aguida, Blanche, and Ahmad, Margaret
- Abstract
Arabidopsis is the plant species in which Cryptochrome, the first known flavin-type blue light receptor, was identified after over 100 years of effort. Even beyond their critical importance to plants, Arabidopsis cryptochromes have had a transcendental impact on many other fields due to the occurrence of homologs in animals and even man with many conserved features. Cryptochromes have furthermore contributed to the emerging field of Quantum Biology, which involves the study of quantum physical phenomena in biology and medicine. Quantum theory predicts that magnetic fields can alter the reaction rates (product formation) of biochemical reactions, including those catalyzed by metabolic enzymes or the biological activity of flavoprotein receptors such as cryptochromes. Therefore, electromagnetic fields could theoretically regulate many agronomically important plant processes, as well as those of other organisms. In this communication we briefly summarize the known effects of magnetic fields in biological systems with the view to identifying possible conserved underlying mechanisms with practical applications for plants. Evidence that Arabidopsis cryptochromes could serve as magnetic field sensors will be reviewed, as well as the role of electromagnetic fields in the formation of ROS (reactive oxygen species). In conclusion, we will suggest workable methods to achieve low cost, environmentally friendly, and broadly applicable crop improvement strategies using tools from Quantum Biology that can be implemented today. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
89. Order Through Disorder: The Characteristic Variability of Systems
- Author
-
Yaron Ilan
- Subjects
randomness ,quantum biology ,biological variability ,evolution ,system biology ,Biology (General) ,QH301-705.5 - Abstract
Randomness characterizes many processes in nature, and therefore its importance cannot be overstated. In the present study, we investigate examples of randomness found in various fields, to underlie its fundamental processes. The fields we address include physics, chemistry, biology (biological systems from genes to whole organs), medicine, and environmental science. Through the chosen examples, we explore the seemingly paradoxical nature of life and demonstrate that randomness is preferred under specific conditions. Furthermore, under certain conditions, promoting or making use of variability-associated parameters may be necessary for improving the function of processes and systems.
- Published
- 2020
- Full Text
- View/download PDF
90. Entanglement in a qubit-qubit-tardigrade system
- Author
-
K S Lee, Y P Tan, L H Nguyen, R P Budoyo, K H Park, C Hufnagel, Y S Yap, N Møbjerg, V Vedral, T Paterek, and R Dumke
- Subjects
quantum biology ,superconducting qubit ,quantum theory ,Science ,Physics ,QC1-999 - Abstract
Quantum and biological systems are seldom discussed together as they seemingly demand opposing conditions. Life is complex, ‘hot and wet’ whereas quantum objects are small, cold and well controlled. Here, we overcome this barrier with a tardigrade—a microscopic multicellular organism known to tolerate extreme physicochemical conditions via a latent state of life known as cryptobiosis. We observe coupling between the animal in cryptobiosis and a superconducting quantum bit and prepare a highly entangled state between this combined system and another qubit. The tomographic data shows entanglement in the qubit-qubit-tardigrade system, with the tardigrade modelled as an ensemble of harmonic oscillators or collection of electric dipoles. The animal is then observed to return to its active form after 420 h at sub 10 mK temperatures and pressures below $6\times 10^{-6}$ mbar, setting a new record for the conditions that a complex form of life can survive.
- Published
- 2022
- Full Text
- View/download PDF
91. Quantum Tunneling-Induced Membrane Depolarization Can Explain the Cellular Effects Mediated by Lithium: Mathematical Modeling and Hypothesis
- Author
-
Lubna Khreesha, Abdallah Barjas Qaswal, Baheth Al Omari, Moath Ahmad Albliwi, Omar Ababneh, Ahmad Albanna, Abdelrahman Abunab’ah, Mohammad Iswaid, Salameh Alarood, Hasan Guzu, Ghadeer Alshawabkeh, Fuad Mohammed Zayed, Mohammad Awad Abuhilaleh, Mohammad Nayel Al-Jbour, Salameh Obeidat, and Aiman Suleiman
- Subjects
quantum tunneling ,lithium ,quantum biology ,voltage-gated channel ,quantum conductance ,depolarization ,Chemical technology ,TP1-1185 ,Chemical engineering ,TP155-156 - Abstract
Lithium imposes several cellular effects allegedly through multiple physiological mechanisms. Membrane depolarization is a potential unifying concept of these mechanisms. Multiple inherent imperfections of classical electrophysiology limit its ability to fully explain the depolarizing effect of lithium ions; these include incapacity to explain the high resting permeability of lithium ions, the degree of depolarization with extracellular lithium concentration, depolarization at low therapeutic concentration, or the differences between the two lithium isotopes Li-6 and Li-7 in terms of depolarization. In this study, we implemented a mathematical model that explains the quantum tunneling of lithium ions through the closed gates of voltage-gated sodium channels as a conclusive approach that decodes the depolarizing action of lithium. Additionally, we compared our model to the classical model available and reported the differences. Our results showed that lithium can achieve high quantum membrane conductance at the resting state, which leads to significant depolarization. The quantum model infers that quantum membrane conductance of lithium ions emerges from quantum tunneling of lithium through the closed gates of sodium channels. It also differentiates between the two lithium isotopes (Li-6 and Li-7) in terms of depolarization compared with the previous classical model. Moreover, our study listed many examples of the cellular effects of lithium and membrane depolarization to show similarity and consistency with model predictions. In conclusion, the study suggests that lithium mediates its multiple cellular effects through membrane depolarization, and this can be comprehensively explained by the quantum tunneling model of lithium ions.
- Published
- 2021
- Full Text
- View/download PDF
92. Analysis of Photosynthetic Systems and Their Applications with Mathematical and Computational Models.
- Author
-
Badu, Shyam, Melnik, Roderick, and Singh, Sundeep
- Subjects
DENSITY functional theory ,SULFUR bacteria ,PHOTOSYNTHETIC pigments ,QUANTUM coherence ,CHEMICAL energy ,PHOTOBIOLOGY ,OPTICAL coherence tomography - Abstract
In biological and life science applications, photosynthesis is an important process that involves the absorption and transformation of sunlight into chemical energy. During the photosynthesis process, the light photons are captured by the green chlorophyll pigments in their photosynthetic antennae and further funneled to the reaction center. One of the most important light harvesting complexes that are highly important in the study of photosynthesis is the membrane-attached Fenna–Matthews–Olson (FMO) complex found in the green sulfur bacteria. In this review, we discuss the mathematical formulations and computational modeling of some of the light harvesting complexes including FMO. The most recent research developments in the photosynthetic light harvesting complexes are thoroughly discussed. The theoretical background related to the spectral density, quantum coherence and density functional theory has been elaborated. Furthermore, details about the transfer and excitation of energy in different sites of the FMO complex along with other vital photosynthetic light harvesting complexes have also been provided. Finally, we conclude this review by providing the current and potential applications in environmental science, energy, health and medicine, where such mathematical and computational studies of the photosynthesis and the light harvesting complexes can be readily integrated. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
93. Toward a Biological Transpersonal Psychology.
- Author
-
Wile, Lawrence
- Subjects
- *
PSYCHOBIOLOGY , *SPINAL canal , *TRANSPERSONAL psychology , *CONSCIOUSNESS , *QUANTUM mechanics , *SPINAL cord - Abstract
Transpersonal psychology's relationship with esoteric traditions has suffered from the severe limitation that esoteric knowledge is ultimately incommunicable and unverifiable. However, the means for obtaining such knowledge might not be. If descriptions by esoteric traditions of a circuit running through the center of the spine, which purportedly connects consciousness with the Absolute or the Divine, are based on veridical interoceptions, then they may be descriptions of Reissner's fiber, a little-known, threadlike structure which originates from the center of the brain and travels through the central canal of the spinal cord. Because the fiber projects filaments to cerebrospinal fluid-contacting neurons subserving oxytocinergic, and endogenous cannabinoid, opioid and psychedelic systems, it could induce feelings of love, bliss, ego dissolution and noesis associated with "cosmic consciousness." Although physicists have decreed that quantum mechanics is a "mystery without a mysticism," direct consciousness of the fiber's quanta could fulfill mysticism's claim of suprasensory perception of the Absolute. [ABSTRACT FROM AUTHOR]
- Published
- 2020
94. The Brain-Mind Conundrum: The Rise of Quantum Biology.
- Author
-
Verny, Thomas R.
- Subjects
- *
BRAIN , *CONSCIOUSNESS , *CYTOPLASM , *MATERNAL health services , *NEUROBIOLOGY , *NEUROSCIENCES , *THOUGHT & thinking - Abstract
All present-day neuroscience is cortico-centric. It's all about the brain. The mind is left to philosophers or theologians to debate. Yet proponents of pre- and perinatal psychology know that we are more than just cells and hormones. While there is no doubt that the brain is material--that is, it can be seen, touched, and measured, and as such obeys Newtonian laws of physics (Classical Physics)-- this materialistic approach is contradicted by hard scientific data from the cutting edge of academic scholarship on Quantum Physics. Quantum Physics stipulates that all matter is made of particles and waves, and in-between states called wavicles. It has taken us from "common sense" to "quantum non-locality"-- revealing an ever more baffling reality. In view of very recent research in quantum biology particularly, by the phenomena of entanglement and non-locality, psychosomatic medicine, the placebo effect, and telepathy, prenatal communication between mother and child, as well as prenatal and birth memories can be understood. [ABSTRACT FROM AUTHOR]
- Published
- 2020
95. Biocognitive Evolution
- Author
-
Peck, Jonathan C., Bainbridge, William Sims, editor, and Roco, Mihail C., editor
- Published
- 2016
- Full Text
- View/download PDF
96. Quantum noise may limit the mechanosensory sensitivity of cilia in the left–right organizer of the vertebrate bodyplan
- Author
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European Cooperation in Science and Technology, Cartwright, Julyan H. E., European Cooperation in Science and Technology, and Cartwright, Julyan H. E.
- Abstract
Could nature be harnessing quantum mechanics in cilia to optimize the sensitivity of the mechanism of left–right symmetry breaking during development in vertebrates? I evaluate whether mechanosensing — i.e., the detection of a left-right asymmetric signal through mechanical stimulation of sensory cilia, as opposed to biochemical signalling — might be functioning in the embryonic left–right organizer of the vertebrate bodyplan through quantum mechanics. I conclude that there is a possible role for quantum biology in mechanosensing in cilia. The system may not be limited by classical thermal noise, but instead by quantum noise, with an amplification process providing active cooling.
- Published
- 2023
97. Aging and group selection: New arguments in favor of partially directed evolution.
- Author
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Melkikh, A.V.
- Subjects
- *
AGE groups , *BIOLOGICAL systems , *QUANTUM biochemistry , *BIOCOMPLEXITY , *ARGUMENT - Abstract
In this study, theories of aging and its mechanisms under various environmental conditions were analyzed. The analysis of published data suggested that aging is a controlled process. It is known that many mathematical algorithms utilize an analogy of aging. However, this is possible only when a "target set" is known in advance. Various forms of selection in relation to aging were analyzed both collectively and separately. The general conclusion is that aging is one of the mechanisms of directed evolution. A model was constructed, which shows how aging is integrated into partially directed evolution. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
98. An Open Question: Is Non-Ionizing Radiation a Tool for Controlling Apoptosis-Induced Proliferation?
- Author
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Samantha J. Hack, Luke J. Kinsey, and Wendy S. Beane
- Subjects
apoptosis ,non-ionizing radiation ,proliferation ,reactive oxygen species (ROS) ,weak magnetic fields ,quantum biology ,Biology (General) ,QH301-705.5 ,Chemistry ,QD1-999 - Abstract
Non-ionizing radiation is commonly used in the clinical setting, despite its known ability to trigger oxidative stress and apoptosis, which can lead to damage and cell death. Although induction of cell death is typically considered harmful, apoptosis can also be beneficial in the right context. For example, cell death can serve as the signal for new tissue growth, such as in apoptosis-induced proliferation. Recent data has shown that exposure to non-ionizing radiation (such as weak static magnetic fields, weak radiofrequency magnetic fields, and weak electromagnetic fields) is able to modulate proliferation, both in cell culture and in living organisms (for example during tissue regeneration). This occurs via in vivo changes in the levels of reactive oxygen species (ROS), which are canonical activators of apoptosis. This review will describe the literature that highlights the tantalizing possibility that non-ionizing radiation could be used to manipulate apoptosis-induced proliferation to either promote growth (for regenerative medicine) or inhibit it (for cancer therapies). However, as uncontrolled growth can lead to tumorigenesis, much more research into this exciting and developing area is needed in order to realize its promise.
- Published
- 2021
- Full Text
- View/download PDF
99. Engineering Transport via Collisional Noise: A Toolbox for Biology Systems.
- Author
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Civolani A, Stanzione V, Chiofalo ML, and Yago Malo J
- Abstract
The study of noise assisted-transport in quantum systems is essential in a wide range of applications, from near-term NISQ devices to models for quantum biology. Here, we study a generalized XXZ model in the presence of stochastic collision noise, which allows describing environments beyond the standard Markovian formulation. Our analysis through the study of the local magnetization, the inverse participation ratio (IPR) or its generalization, and the inverse ergodicity ratio (IER) showed clear regimes, where the transport rate and coherence time could be controlled by the dissipation in a consistent manner. In addition, when considering various excitations, we characterized the interplay between collisions and system interactions, identifying regimes in which transport was counterintuitively enhanced when increasing the collision rate, even in the case of initially separated excitations. These results constitute an example of an essential building block for the understanding of quantum transport in structured noisy and warm-disordered environments.
- Published
- 2023
- Full Text
- View/download PDF
100. Magnetic Field Intervention Enhances Cellular Migration Rates in Biological Scaffolds.
- Author
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Vecheck AM, McNamee CM, Reijo Pera R, and Usselman RJ
- Abstract
The impact of magnetic fields on cellular function is diverse but can be described at least in part by the radical pair mechanism (RPM), where magnetic field intervention alters reactive oxygen species (ROS) populations and downstream cellular signaling. Here, cellular migration within three-dimensional scaffolds was monitored in an applied oscillating 1.4 MHz radiofrequency (RF) magnetic field with an amplitude of 10 µT and a static 50 µT magnetic field. Given that cellular bioenergetics can be altered based on applied RF magnetic fields, this study focused on a magnetic field configuration that increased cellular respiration. Results suggest that RF accelerated cell clustering and elongation after 1 day, with increased levels of clustering and cellular linkage after 7 days. Cell distribution analysis within the scaffolds revealed that the clustering rate during the first day was increased nearly five times in the RF environment. Electron microscopy provided additional topological information and verified the development of fibrous networks, with a cell-derived matrix (CDM) visualized after 7 days in samples maintained in RF. This work demonstrates time-dependent cellular migration that may be influenced by quantum biology (QB) processes and downstream oxidative signaling, enhancing cellular migration behavior.
- Published
- 2023
- Full Text
- View/download PDF
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