Ýyorhïsïb

Ýyorhïsïb, or Eovrisibb, is the act of reproduction in the culture of the Ibrófeneð species. It is widely seen as a duty in life to reproduce, and it is common for closely-related Ibrovinids to engage in Ýyorhïsïb. Instead of taking place inside an individual, it takes place entirely externally and in a designated pit.

Typically, to reduce confusion, all terms mentioned below will have the prefix Ýsïb- attached to it when used in casual conversation.

Anatomy

The Rertüp (Gúvra)

The Rertüp (literally 'one that secretes'), also known as the Gúvra ('entrails', or 'insides'), is the bodily cavity in which the reproductive cells (Mabëžaró) are created and stored.

Both species are equipped with two small chambers each that both empty into the underside of the creature. For Ibrovinids, the chambers' pathway is connected to the digestive tract, located below the last set of teeth, whereas in Canotus the chambers are each given their own funnel separate from the digestive system. Both chambers, regardless of species, contain what is known as Mabëžaro. This is essentially the reproductive cells and is what will be secreted during Ýyorhïsïb. The exit for each chamber is sealed off with a thin yet relatively sturdy layer of mucus, called the Ëžú, which stops the cells from leaking out.

In one chamber there is Au-Mabëžaró and in the other there is Ze-Mabëžaró, which are the two different cells involved in Ýyorhïsïb. An Au-Mabëžaró can only react with a Ze-Mabëžaró because the chemical composition is specifically made to be unreactive with members of its own type. Moreover, once a creature does Ýyorhïsïb, the type it has voluntarily chosen will be the only type it can access, and the other chamber will be sealed off and its contents recycled for the body. Because of the unique composition of these reproductive cells, they will only manifest as small discolorations in newly-grown scales. The type it's chosen becomes the creature's "gender" and from then on, it can only do Ýyorhïsïb with those of the opposite gender.

The MabëŽaró

Main Article: Mabëžaró

Every cell consists of a weak membrane fitted with small hooks and receptors, and the inside is filled with a chemical concoction. The membrane is characterized by a recognizable hexagon pattern, with the edges being intentionally-weak fracture lines and the center fitted with a small magnet. When the seal at the entrance of the chamber is broken via the forcing of the cells out, the surrounding air on the outside are trapped by the hooks and the seal, creating a "mega hook" which allows it to pick at the cells of the corresponding type more easily. Mabëžaro lucky enough to be the first ones out, and thus receive the 'mega hook', are called Leader Cells, or Hývamupó.

Internally, each Mabëžaro contains about 90-95% chemical ingredients, bound up in their own mini-cells called Mabëtó, that make up the Ibrófeneð itself, and the cell membrane itself contains silicon-rich building blocks that aid in bone strength and overall cohesiveness. The exact identities of these Mabëtó depends on which body part they are to become. Similar to the Mabëžaró itself, the Mabëtó is covered in hooks, which can only be opened by the Mabëtó of the same body part from the opposite gender.

The rest of each cell's components, the 5-10%, are what are called Pëlanupó, or Rush Cells. These are comparatively small objects, about 5 times smaller than a Mabëtó, that are attached to specific fracture points in the cell's membrane by elastic cords. Internally, they are relatively sparse in composition, fitted only with a magnet at its front end. When the cell membrane is broken, it will break along these fracture points, and the resulting movements will project the Pëlanupó outwards at speeds of up to 20 km/h. The broken cords are reeled up into the magnet to power it, directing it straight towards the magnets fitted on the cell membranes of other cells. These Pëlanupó are the main catalysts that spread the actions of the Leader Cells out to the other cells.

Magnets

This section describes the use of magnets in Ýyorhïsïb in order to lessen the confusion brought on by later sections. The Mabëžaró consists of two types of magnets: those embedded into the membrane itself and those attached to the Pëlanupó. The former are built into the membrane when the cells are first being made. They are also integral to the structure of the entire cell as any other component; this is why they are seen as the weak points, as their magnetism attracts the Pëlanupó and/or the Leader Cells' hooks. The latter are not built into the membrane, but are embedded in the tips of the Pëlanupó, which sit just behind the membrane itself, in order to reduce interference. These two magnets work in tandem; when the membrane magnets are pierced, the cell membrane fractures, and this fracturing directly propels the Pëlanupó magnets.

For the membrane magnets, they are frequently altered over the course of Ýyorhïsïb; when the Leader Cells receive the giant hooks, that part of the cell undergoes a rearranging of the membrane; most of its parts covered by the bubble are recycled for the strengthening of two membrane magnets located on the edge of the bubble area. The remaining membrane fragments have just enough strength to prevent air from the bubbles leaking into the cell itself, and the magnet most covered by the bubble is detached and allowed to float freely in the bubble area, although the membrane structure blocks it from going inside the cell itself. Usually, this magnet will be guided towards the tip of the bubble, where it steers the cell towards the strengthened magnets of the other Leader Cells.

Process

Ýyorhïsïb usually happens in a small bowl or bowl-like structure, preferably outside. Standard convention dictates that the bowl should be at least two meters deep, and modern structures constructed specifically for this purpose, called Prëdurëp, come with a drain and a rope-pulleyed platform. These precautions are mainly due to the fact that the Mabëžaró cells, regardless of gender, are extremely toxic to Ibrófeneð skin once activated. Skin contact results in tumors, and if structurally sensitive body parts are exposed, like teeth, joints and muscles, immediate care and removal is imperative to avoid an amputation.

Secretion (RertüŊ) and First Phase (NarünïŊ)

Generally, Rertüŋ is not considered part of Ýyorhïsïb; the honor of starting this process is given to Narünïŋ (literally translated as 'dance', named for the coalescing, swirling motions exhibited by the cells).

The Au-Mabëžaró usually is secreted first, as their contents are, on average, more potent that than of their counterpart. Then, the Ze-Mabëžaró is secreted, and the two cell membranes interact. The cells that broke through the membrane, called the Leader Cells, have pieces of the mucus membrane, that is, the membrane of the bodily chambers keeping the cells inside the body, stuck on their own cell membranes. Between the cell and mucus membranes is a pocket of trapped air, which is manipulated by the hooked surface of the cell to create a mega-hook. These Leader Cells have two major enhancements: their larger hooks allow them to pick apart the membranes of the opposite Leader Cells, and some of the trapped air reacts with special receptors in the membrane that disintegrate some small pockets of the cell membrane coated by the mucus membrane to strengthen the magnets around the mucus membrane, causing the Leader Cells to naturally drift towards one another. This disintegration is extremely slight, so as to maintain structural integrity as long as the air bubble is intact, but it creates small vulnerable spots in the membrane that, if touched, will break the mucus membrane and, because the structural integrity of the cell membrane is now gone, break the internal contents of the cell out.

The hooks of the Leader Cells are about three times as long as their regular counterparts, so regular cells are unable to reach deep enough to pop them as is, but the hooks of Leader Cells are well-equipped to do so, and the magnets are specifically placed to encourage this. Once this initial pop happens, Narünïŋ is over.

Second Phase (Žimarkup)

The Second Phase, called the Žimarkup, or Spiritual one, begins when bubbles begin to appear, signaling that the trapped gas has been released. This seemingly miraculous event has maintained a level of notoriety in Ibrófeneðian culture, exemplified by its name, as it is at this point where life was traditionnally said to begin; after this point, the vast majority of law systems around the world categorize the premature abortion of Ýyorhïsïb as murder.

The gas that bubbles out of the mixture, is the trapped gas that makes up the 'mega hook' of the leader cell. Since some crucial parts of the cell membrane were reused as magnetic components (see above section on Narünïŋ), the mucus membrane and its trapped air bubbles constitute an integrally structural role for the cell. Since this membrane is gone, and its air bubbles escaped, what is left of it is a gaping hole in the cell's membrane, allowing the internal ingredients, the Mabëtó, to escape.

Once the cell membrane's bubble is popped, the rest of the membrane, which forms along thinly-held-together fracture lines, subsequently breaks along these such fracture lines. Within these cracks are attached the Pëlanupó, discussed in the Mabëžaró section, which, propelled by the fracturing of the membrane, shoot off towards other cells. They are guided by magnets at the front end, which bend their trajectory towards the magnets embedded in the other cells. Once struck, the new cell will fracture, and its Pëlanupó will shoot off, thus creating a chain reaction.

The last step in the Žimarkup is the dissolving of the cell membranes and the Pëlanupó once their job is done. This material will become the base material the developing Ibrófeneð will use to form its skeleton and parts of its brain.

Third Phase (FýtaŊ)

The Third Phase, known as Fýtaŋ, or the creation/assemblance, uses the Mabëtó to form the basis behind what is to be the Ibrófeneð. Each Mabëtó contains about 60-70% Fýtap (building material), 20-30% Yartap (lit. 'controller', or director; essentially DNA), and 10-20% Khošŋo ('bridge'), which takes a strand of Fýtap and a strand of Yartap and begins to fabricate the body part based on the instructions of the Yartap. This is not a full-fledged body part but rather a shell. The Khošŋo will often embed itself within the hollow shell itself such that any material suitable for building that floats into the shell will be incorporated into it. Without additional nutrients from the outside, a body part can fulfill up to 15% of its required amount by simply using the residual nutrients left over by the cell membrane and the Pëlanupó. This stage is extremely active, characterized by highly turbulent and seemingly miraculous motion; this Fýtaŋ phase was once incorporated into the earlier Žimarkup phase. When the waters calm down, this is its signal that it is ready for nutrients, which may be hard to detect in volatile weather.

Fourth Phase (GúfaŊ)

The Fourth Phase, known as Gúfaŋ, or the finish, requires nutrient input from those supervising the process. This is also the stage in which the mixture becomes extremely volatile and reactive, which it must become in order to properly incorporate these nutrients. To become reactive, it uses trace elements like hydrogen, chlorine, and fluorine to make powerful acids, which redissolve any existant nutrients in the pool and incorporate any external nutrients in the mixture, both from the air (Oxygen, Sulfur), and from solid material. This is where the caretakers and/or any other nearby individual must dispense solid, measured chunks of rock, as collection from the air itself only accounts for 10-15% of the total.

A further 50-60% of the nutrients comprises silicon, which is added as large chunks of silica rock. This is very easy to acquire, as the rock is widespread in over 80% of the planet's surface. This silica also comprises the bulk of the oxygen content. A further dose of oxygen, and the creature's main supply of hydrogen, is supplied via solid ice. Nitrogen and Sulfur are supplied by Saltpetre and Pyrite/Galena, respectively. Once adequate amounts of all of these elements are deposited, the pool becomes visibly segmented in appearance, as the different molecules migrate across the pool, driven by electrostatic forces. These segments correspond to the various parts of the finished creature, notably the Matošu, Žëša, and the Vëtiš. Upon the end of the Gúfaŋ, these regions are fully sequestered and separated from each other by a thin film made from the cell membranes of the Mabëžaró.

In the lower portion, which possesses a characteristically dark blue color, this place houses the future location of the legs, or Vëtiš, and, in this specific place, a roughly fist-sized amount of carbon, an element normally toxic to most of the creature, is carefully deposited in. This amount will combine with the silicon supply to serve as the bulk material for the Vëtiš-Húrobü and the leg in general.

Despite beng referred to as the 'finish', the Gúfaŋ is not the last step. The name comes from the fact that this is the last major intervention of the caretaker, and after this point, the caretaker's job is thus 'finished'. This is not to say that the pool can be left without supervision, and even the etymology incorrectly simplifies the role of the caretaker. Instead, he must wait another month for the true last phase, the Pavamaŋ, to end, in which his main role transitions to that of a guard, both against natural interference (winds, contaminants from natural disasters) and sabotage interference.

Fifth Phase (PavamaŊ)

The Pavamaŋ, or Assembly, is the last phase of the Ýyorhïsïb process, and involves the actual building up of the creature's body. Each of the three layers develops under separate reactions. Thus, this section will run through each section individually.

PLEASE NOTE: I have a very rudimentary understanding of chemistry/biology, and most of these elemental compositions are taken simply from Chatgpt. However, the mechanisms themselves I have created on my own.

Matošu

The Matošu is a long flexible tube attached to the top of the Ibrófeneð's head. It forms part of the digestive system and aids in stability and movement of the overall creature.

Regarding its role in the Pavamaŋ stage, the Matošu is the last body part to form, as it requires the formation of the outer skin of the Žëša to anchor itself. When the Žëša's skin is developed, the manner in which it forms causes a designated hole in its skin to appear at the sphere's contact with the Matošu, where the axis of rotation is. The spinning motion of the Žëša builds up friction on the film separating it from the Matošu, and it breaks through, but not enough to cause mixing of the two regions. Instead, what occurs is that in 2 seconds-worth of time, the broken film rebinds to locations close to the edges of the exposed Žëša skin, leaving the actual edge unbound for the construction of the Matošu itself while keeping the two pools separate.

The Matošu is thus built from the exposed root of the Žëša's skin, and 80% of the silicon is used in a flurry of chain reactions that fully build the framework for the Matošu in as little as 1 day. This will become the the inner skin layer, and what is built on it is further reactions involving trace materials with the leftover silicon, which makes rope-like bands that adhere to the Matošu and form the muscular system for the body part. This is the most time-consuming step, taking around 1-2 weeks, during which the bulk of the internal components of the Žëša are created. During this step, the thin film is actually broken, and trace materials in this region mix with the silicon-rich pools of the Žëša to create the Оö-Vanýst.

When the barrier between the Vëtiš and the Žëša is finally broken, and the nutrients from the former flood in, some trace amounts of it meet the Matošu, whereupon they aid in the creation of the final outer layer of the Matošu, thus finishing it.

Žëša

The Žëša, or the head, is the most complex and densely packed area of the organism, and as such, it takes the most reactions and steps to develop. Its most characteristic aspects, that is, its bulbous shape and radial symmetry, are chiefly the result of the slippery quality of the pool liquid acquired, which douses the various components and causes it to spin from side to side as different parts are formed. The axis of symmetry is a line that roughly bisects the pool in half, and goes through the middle of all three regions.

Ýyr-Üpal

Initially, the outer skin, which will become the Ýyr-Üpal, is developed at the interface between the pool and the air. As it accumulates mass, it begins to become more unstable, to the point where even a slight disturbance will cause it to shift, where it spins to the bottom and exposes another unformed layer of liquid to the surface. This repeats three more times, which together form the frame of the Žëša. At the ends of each layer, the unpolished edges, shielded from the air by the sides of the vessel, are linked together, either through direct contact between two layers or through further reactions with molecules in the bulk medium. This first set of reactions results in the formation of a solid, mostly unbroken spherical skin, which surrounds the other liquid in the zone. The exception is that, at the axes of rotation, the surface area of the liquid is not big enough to allow one to fully stitch them together. Far from being detrimental, these two holes will become the joint for the Matošu and the placement for the Matrüka, respectively.

Once the skin has been fully completed, it is expanded by gases inside it to become fully spherical, and although initially flimsy in strength, it is gradually reinforced by chemical reactions that render it able to stand on its own. These reactions involve both the liquids and gases present in the system. The two holes still left are still able to contain the resources and air inside due to the airtight contact surfaces they have with the films dividing the Žëša from the other two regions. Inside, the liquid level is typically at 3/5 to 2/3 the width of the skin.

Оö-Vanýst

Once the Žëša's outer skin has been fully formed, it no longer consumes the gases, and so, the liquid and gases begin to interact in full. Here, the first segments of the brain and the various nutrient transport vessels are created; these involve very little silicon and large amounts of other elements like Nitrogen and Oxygen, respectively. Initially, the vessels will form as little tubes in solution before being attracted to and adhering to the Ýyr-Üpal. From there, the magnetized ends of each vessel attracts further construction.

From these reactions, the liquid level dips to around halfway, and, detecting this, the film with the now-formed Matošu weakens and gives way, allowing full mixing between the two regions. The same chain reactions that created the Matošu with such alacrity now occur between the silicon-rich Žëša and the silicon-depleted Matošu regions, and the combination thereof creates a thin frame much in speed and composition as the inner frame of the Matošu. The buoyancy of the material causes the frame to be highly dependent on the liquid level for stability, and the intermixing of materials from the two regions allows it to be steadily around halfway. Additionally, the stability of the outer skin allows resistance from external forces.

The elements typically used in the construction of this central tube are oxygen, nitrogen, fluorine, and chlorine. First to be used is mainly the oxygen, which forms the first few lengths, around 5 centimeters, before nitrogen is used. Around two-thirds of the way through, the nitrogen supply runs out, and fluorine and chlorine supplies are tapped into. The different compounds made give the remaining 1/3 of the tube a distinctly jagged texture compared to the smoothness of the earlier nitrogenous tubing.

Оö and Súro

It takes roughly 1-2 days for the frame to be fully built and contact the Matrüka on the other end, at which point the tubing (that is, the Vanýst) is finished. From here, the other components of the Žëša are manufactured around this central tubing, and are regulated from favoring any direction over another via the constant spinning of the outer shell. The segments of brain, or Súro, produced earlier begin to coalesce around the upper sections of tube, attracted by the nitrogen in that section. They grow at a moderate rate, but their finished size is around two times as massive as the next most massive component, the Оö-Ëtavú, which conveniently forms simultaneous to it. Even after the bulk of the brainmass is formed, the nerves extend past the edges, forming available bonding ites that will be used later on.

Thus, the presence/absence of nitrogen is the delimiter for where the brain forms, with the oxygen, fluorine and chlorine parts being kept bare. Instead, in these parts, the rest of the silicon is used in bulk to create the organism's skeleton, or Оö. The top part of the tubing, the oxygenous part, forms a thick layer of silicates which grow at a rapid pace and are sculpted by the brain into a thick canopy; this is the Оö-Ëtavú. In the Fluorinated and Chlorinated section, the silicon takes a very different shape, influenced mainly by the different chemistry of these elements and forming a very fragmented and stretched piece of bone called the Оö-Ŋüžtú. It is this random chemistry that forms little pockets in which the storage compartments and reproductive cavities are held.

Tewaðup

Since the two pieces of bone contribute so heavily to the overall mass, the shift in mass distribution causes the spinning to slow down. From here, the residual materials left in the making of the central tube recombine not into the tube, but as separate compounds, many of which are acidic. and strongly charged, as such, they are repelled from each other, and reach equidistant places along the tube. Initially, there are millions of these such compounds, which begin eating into the tubing. As they do so, they lose their charges, and, in the absence of these electrotatic forces, begin coalescing, even with those that have not lost their charges. The result of this coalescing is that the millions become five distinct colonies of these molecules, each of which interact within each other, separate into two groups, bind to specific spots on the tubing, and continue eating away on their designated spots. This continues until full-on holes are drilled in, and the liquid from the surroundings then floods in, diluting the acidic compounds and neutralizing them.

The Оö-Ëtavú and Оö-Ŋüžtú then use the newly dissolved and broken-down compounds to extend into the tubing through the holes, forming the first few Tewaðup, or teeth. This is not highly regulated except through the gradual erosion by the liquids now inside the tube. Once the teeth have grown through and contacted each other, the supply of bone for these is mostly depleted, and the process of formation stops. The liquid, constantly drained into the still-empty cavities between the brain and the Vanýst, collects the dissolved components of bone in these cavities, where they mix with and use up the last of the trace compounds in the liquid to form the remaining few teeth. These last teeth, namely the E and I teeth, are differentiated by their slightly off-white coloring, which was from the incorporation of many discrete compounds, including a minute amount of the brain itself.

Muscular System

It is at this time that the film between the Žëša and the Vëtiš is broken, and the excess nutrients from the latter flood in. Crucially, all carbon deposited into the Vëtiš region must have been fully consumed to avoid warping and excessive reactivity. What occurs then is that the nutrients, which comprise 50% silicon and 30% Fluorine, flood throughout the Žëša and gather around the exposed nerves of the brain. These nerves are specialized; their composition dictates the types of reactions that occur there and subtly direct them to their destinations. As such, the majority of short-range muscles are formed here, including those of the teeth and of the future components like the eyes, as well as those connecting the brain to extremities like the Matošu. However, if the muscles are too long, they become weakened and stretched, resulting in redissolution. This is the case for the legs and the feet, which results in several failed attempts at connection, each of which uses up precious materials and isolates elemental silicon, which coalesce near or at the closest location, which is at the border between the brain and the Оö-Ŋüžtú. The small ring formed here subsequently attracts the muscular components, which form the system around the ring, which is known as the Оö-Fýtap. Crucially, this ring must include at least some amount of ferromagnetic material, which will come in handy during the binding with the Vëtiš.

After the Оö-Fýtap has been created, the Žëša is said to have finished construction, and the Ibrófeneð is born. However, it is only shortly after the complete conjoining between the legs and the head that the Ibrófeneð can be removed from the pool.

Vëtiš

The Vëtiš is the location of the legs, and it is in this portion that the carbon was deposited. As such, the Vëtiš's process of formation begins before the official beginning of the Pavamaŋ stage with the combination of carbon and silicon into cylindrical, flexible, sponge-like material called the Vëtiš-Húrobü.

Vëtiš-Húrobü

This is actually not formed at the location where the legs are to be joined to the Žëša, but right at the Matrüka, or anus. Much like how the Matošu arises as an extension of the top hole in the organism, the legs emerge as the extensions of the bottom hole. Unlike the Matošu, the inclusion of carbon means that instead of sticking to a simple frame structure, the material actually fills in the cylinder further with the carbon-silicon molecules. due to the configuration enforced by the junction with the Matrüka, the outside of the cylinder is and remains very resistant to chemical alteration, but the inside is very volatile. The process behind the formation of the outer edges of the leg material is alway a bit ahead of the process behind filling it up, as it must wait for water to flood the inside and move with a speed large enough to properly supply a constant dose of carbon.

When a Vëtiš-Húrobü has grown to the point where its edges touch the pool wall, it detaches from the Matrüka, as the bonds there are too weak to prevent the now-dense leg from sinking. Due to the delay, the leg is not completely filled with the carbon-silicon material, but a small cavity exists instead, which will grow to be the compartment for the gel used in the organism's suction cup mode. This process of growth, filling, and detachment repeats itself over and over again for all 8 legs, until there are 8 legs at the bottom of the pool. For each one, the exposed carbon at the ends allows some more silicon to bond with it, but due to it being at the very end, bonds are directed in the opposite direction as the rest of the leg. Thus, at the top and bottom of each leg is a small ring of silicon, on which are more exposed molecules for bonding. At least a select few of each ring's bonding sites are attacked by sparse amounts of magnetic material like iron, resulting in electrostatic forces powerful enough to separate each of the 8 legs at equidistant places in the pool.

Vëtiš-Mëta

Concurrent to the formation of the Vëtiš-Húrobü is that of the Vëtiš-Mëta, the system of muscles that govern leg movement. these are actually made from the same elemental composition as that of the other body parts, namely Silicon and Fluorine. These grow into arbritrary lengths of around 1-3 centimeters, which become attracted to the two rings and connect together at specific points, forming the inner layer of muscles. However, when they bind as such, they change the chemical composition in such a way that both rings rotate inside out, exposing a different set of binding sites. In addition, either the top or bottom ring rotates such that the inner muscles are stretched somewhat, and it is in this stretched mode that the outer set of muscles is formed in much the same fashion as the inner ones. This results in one set that is stretched diagonally (and thus rendered inactive) and one set that is straight up and down (and thus rendered active). The ring will be compelled to rotate again a few more times back and forth during the formation of the last layer, the Ýyr-Vëtiš.

Ýyr-Vëtiš

The Ýyr-Vëtiš is the last layer to form, and it is mainly the result of the exposed sites in the Vëtiš-Mëta when stretched. The most prominent binding sites are on the inner layer, as they spend the most time in the stretched mode. However, there are also binding sites on the outer layer as well. Regardless of the location, binding sites typically grow into large filaments that, when an adequate distance away from the muscles, begin forming a thick layer of skin, eventually encasing the entire leg in it. This covers all parts of the leg, even those that will become the eventual foot. Not only does this serve as the main protective layer in the leg, but it also protects nutrient loss, as it is around the finishing of the Ýyr-Vëtiš that the border between the Vëtiš and Žëša pools is broken, causing a rapid mixing of substances from both of them. If the leg is not properly cased, devastating nutrient loss may be caused by the immense water currents that arise during the breaking of the film.

Binding to the Žëša

The Vëtiš and Žëša bind primarily through the use of the existing magnetic separation, which already places the 8 legs at the farthest-away distance they can be from one another. In the Žëša, the erratic formation of the Оö-Ŋüžtú causes the attraction between the legs and the Оö-Fýtap to be variably strong depending on the location, as places with more bone will do more magnetic shielding in that regard. However, given the radially-symmetric nature, the Оö-Ŋüžtú will always be symmetric on all sides, and due to its depleted nutrient supply, it will always have some large-enough cavity adjacent to the wall to which the legs will be most attracted.

It is at these weak spots that the legs slam into the Žëša, pushing the Ýyr-Üpal in. The pieces of bone surrounding the skin will help to mold the skin in this new position to prevent collapse, and particular chemical reagents both inside and outside the Žëša help to bind the head and legs together. The folded-in skin thus becomes detached, redissolved, and handily resupplied as the basis for the nerve and vascular systems connecting the legs with the Оö-Fýtap.

Social Effects

Ýyorhïsïb is largely seen as a universal duty, or Ðývhëtaki, of all Ibrófeneðs.