The Deep Facial Remodelling

Socio-Magickal approach:

• An endo-skeleton ‘wear’ methodology with the fully finalized model of a remodeled skeleton. inspired by exoskeletons and targeted to the full skeletal system, including the face bones.
• Facial identification techniques (future) used for appearance registry in the subconscious of current viewers.
• Elemental balance targeted to the facial construct; refilling the blood and capillary system with purified blood and mana.
• Established social and power dominance through the face
• The Essence of Luxury and Royalty targeted to the face

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Smart Objective Analysis

Multiscale model of bone can alternative material parameter of any hierarchical level to determine its effect on bone properties, such as porosity, elastic modulus, and permeability

the idea of mechanical stimulation is the geometry, internal structure, and function of the affected areas. the behavior of the muscle / bones is defined by the location and magnitude of forces. the form predicts the function and therefore, malfunctions can be observed in forms that have deviated from their original placement. The field draws from this data via calculated geometric morphometrics and computational (morphic) biomechanical analysis.
bone strength is determined by its structure, and bone structure is regulated by external mechanical stimuli and intelligently adapt to mechanical environment (Bone-microstructure)

• A conducted analysis that measures stress distribution, deformation, and potential areas of weakness and deploys its working accordingly.
• Elicited signals of Neuromedin U on the occasion of reaching a certain bone mass levl to start a bone resorption process as a protective measure.
• Measurement of the torsional behavior and compressive strength in the facial region along with elasticity to ensure the proper mechanical properties.
• Mathematical Intelligence targeted to the facial construct that adjusts the face according to Royal structures.
• Measurement of fluid pressure (FP), fluid velocity (FV), von Mises stress (VMS), and maximum principal strain (MPS) to create a plasma transmission system to connect interstitial fluid, cells, blood, and extracellular fluid to address fluid shear stress and bone mechanics.

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Surgical approach:

The objective is to provide the results of the following treatments through the addressed methodologies and other popular methods available in the plastic surgery industry. Through bone remodeling, the concept focuses on the treatment of bone resorptive diseases.

Craniofacial reconstructive surgery and Extended Deep Plane Facelift. The Facelift is comprised of the following procedures:

• Deep Neck Sculpting.
• Endoscopic Brow Lift.
• Eye Beautification. (Endoscopic reshaping and contouring of the forehead, brows and the upper eyelids, lower and upper Blepharoplasty)
• Deep tissue sculpture. (Deep Fat reshaping, ant dag debulking, salivary glands reduction)
• Targeting the 3 compartments of Fat (superficial musulo-aponeurotic system, superficial fat compartments, and deep fat compartment) and reversal of upper cheek sagging
• Extension of the muscles of the neck and under the chin.
• Oral-Motor Physiological Effects - peripheral speech motor system
• Inducing symmetry and firmness between the tissues on both sides; the soft tissues maintain a degree of firmness and definition and well-defined contours are obtained in semblance of vitality and health.
• Shifting the visual weight of the face to be of elemental harmony.

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(1)

Mechanobiology:

a midline mandible load at the coronal plane, a posterior load at the sagittal plane, and the force generated brings hold to the six attachments in the zygomatic area. the maxilla is connected by six main vertical trajectories to the orbitozygomatic frame; reattachment of these areas via applied force is the goal.

• shifting the load points towards the fracture / area with less density; keeping in mind the arch bar sensitivity
• enforcing the ideal length for each muscle at the sarcomeres level in the facial region to generate appropriate force and promote optimal muscle function
• Identifying the six motions of the zygomatic zone at their bi-zones and preventing the defects associated with them. (at rotation and translation)
• reversal of the defects in the zygomaticular complex resulting in facial asymmetry. reassembling the attachment forces to the sugama (masseter attachment, downward vector of force in the zygoma) and also on the facial attachments.
• increasing the mechanosensitive growth factor MGF24E to stimulate MSAD phosphorylation and express osteogenic genes for higher bone mineral density.
• Repairing mechanosensitivity at the level of multiple mechanosensitive structures such as cytoskeleton, dendritic processes, integrin-based focal adhesions, connexin-based intercellular junctions, primary cilium, ion channels, and ECM.
• Increasing GLAST in osteoblasts as a result of mechanical loading (N-methyl-D-aspartate NMDA type)
• Introducing change to bone geometry via the induced mechanotransduction and cellular information; this leads to increased trabecular volume, cortical thickness, and connectivity between the bone tissues.
• Training the tissues of the middle-lower third of the face and neck using targeted exercise that target the soft tissue and the muscle areas of the face (faceflex)
• Readjustment of cortical porosity towards decrement to prevent bone loss.

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Application of Force:

Adjustments are made to the bone metabolism process, bone fluid movements, skeletal muscle traction and ground/impact reactions.

• Forces to the cranium and facial skeleton can be applied from anteroposterior, superior, inferior, and lateral directions.
• Midline mandible load at the coronal plane and posterior load at the sagittal plane are applied, aiming to reconnect the specific areas via applied force.
• Increasing load sensitivity targeted to the bone structure and biomechanical load for rebuilding with adjacent contribution to the proper function of the masticatory apparatus
• Application of force at angular distributions of the dental formations to create a stabilized shape and support

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Nervous system approach:

• Activating the proper nerve connections through establishing the bone-brain axis via the release of osteocalcin, OSTEOPONTIN, lipocalin2, and FGF-23) to establish communication between bone and brain. the changes enable a stern communication between the brain and bone.
• Increasing the stimulation of acetylcholine to establish brain-bone communication.
• Inhibiting B-2AR to increase osteoblast formation and function.
• Increased production of osteocalcin - bone derived proteins and its chain reaction starting at the pre-pro-peptide level and Lipocallin2.
• Activation of neurons in the paraventricular nucleus and the MC4R pathway.
  Parasympathetic innervation of the bone: AChR types like MLO-Y4 have been detected and their levels have been identified by ACh, muscarinic AchR type M1, M2, and M4, have been identified in osteoblasts.
• Restraint of bone resorption via releasing nAchR agonists and promoting healing of the parasympathetic nervous system.
• Increased production of Semaphorins, particularly sema3A released by sensory fibers to promote bone mass gain and deterring osteocyte elongation through interaction with Nrp1 receptor and Plxna 1, 2, 3 co-receptors.

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(2)

Cellular approach:

the work in this field targets the refinement of the mechanical energies (potion) within the skeletal system located within the face. the cellular environment is enhanced using the following approaches:

• the bone cells gain resilience and adaptation to the new improvements; the cells gain the data / information necessary to morph into the shape of complete bone formation and bone remodeling process.
• The proliferative and differentiative capacity is increased via activation of the receptor of nuclear factor xB by the Rank Ligand.
• Osteoclasts function is regulated through mechanical stimulation and the expression of RANKL by osteoprogenitor cells.
• Repairing sensitivity in multiple mechanosensitive structures such as cytoskeleton, focal adhesions, ion channels, and ECM.
• Inhibiting sclerostin and DKK1 while activating the Wnt ligands pathway for direct stimulation of osteoblastogenesis and migration.
• Releasing appropriate integrins and focal adhesion points and repairing ECM to regulate bone mechanobiology.
• Preventing osteocytes apoptosis and promoting ERK activation.
• Modulating EVs cargo in the cytosol. with direct commitment to the target cell to create the biological response.

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Biological approach:

• Resolving endocrine and paracrine stimulations and deficiencies related to the bone remodeling process.
• Recognizing CGRP and substance P for stimulating osteoblast proliferation and activity, influencing the bone process.
• RNA Approach: miR-26a was for bone regeneration. - miR148b formation of bone tissues; upregulating BMP-2 gene and promoting osteogenesis. - Sema4d for bone - brain axis communication.
• Blocking formation and exocytosis of lysosomes and decreasing the ability of osteoclasts through inhibiting ruffled borders and acidic resorption using coumarin-type aescultin natural therapy
• Suppressing osteoclastogenesis via Inhibition of tumor progression locus 2 (Tpl2.)
• Increased bone mass via deletion of sestrin 2 and reducing the number of multinucleated osteoclasts on bone surfaces. The impact is regulation of NFATC1 and the TRAF6/P62 interaction.
• Macrophages therapy: bone marrow macrophages regulate hematopoiesis and bone formation, progenitors derived from bone marrow are also able to formulate new bones and tissues
• Targeting MALPS for bone resorption as they are the major cell type controlling bone resorption. and down regulation of Tnfsf11 results in decreased resorption.
• Enhancing osteogenic proteins via RNA delivery: PDGF-B gene resulted in human bone marrow stromal cells. VMP-2 and FGF-2 genes
• Peptide therapy: the treatments of peptides attach themselves to the bone fracture / lesser bone density regions: NOV004, peptide treatment.
• Inducing the necessary chemicals for skeletal regulations such as PIEZO1 and MicroRNA-103a- mediate skeletal mechanosensory regulation
• Increasing collagen production of all types targeted to the skeletal / bone system. and their relative peptide procollagen type 1 N-terminal propeptide (P1NP) and procollagen type 1 C-terminal propeptide (P1CP).
• Induced TSHY/FSH signaling to regulate bone formation and remodeling, decreasing osteoclastogenesis, and promoting osteoblastogenesis.
• Induction of hormones such as arginine-vasopressin (AVP) and (ACTH) to stimulate osteoblast formation.
• Inhibition of DKK1 and FGF-23 as it corresponds to bone resorption favoring. and blocking RANKL-RANK binding. Decreasing the concentration of M-CSF to block the binding of Rank expression
• PFD5 peptide mimics certain proteins of the bone extracellular matrix, with calcium phosphates particles, it induces biomineralization of hydroxyapatite, an essential ingredient that gives bone their rigidity.
• Enhancing osteoblast activity through the Agouti-related peptide favoring bone mass gain and elevated CART expression [cocaine - amphetamine regulated transcript]
• NPY and y1 Receptors are found in the osteoblastic lineage. local NPY alerts the system to mechanical stimulation and works in central signaling to elicit anti-osteogenic effects on trabecular but not on cortical bone.
• Modulating the BRB system via the production of IRISIN targeting the CNS system.
• Activating the YAP/Taz protein system as mechanosensors and transducers, committing directly to the nucleus.