The Su God of the Reopening of the Sports Arena

Chapter 2197 The Extreme Prospect Player's Speedy Dragon Gate! Has Been Opened!!!
Open quickly.

break out.

Transient actuation of the phosphagen system.

Bang bang bang bang bang.

Utilize the conversion of gravitational potential energy and kinetic energy during sprinting.

Optimize the vector of ground reaction force!
Ground reaction force is the key external force driving energy conversion, and its magnitude, direction and duration of action directly affect energy distribution.

Su Shen is able to maximize the horizontal component of the ground reaction force through technical optimization.

Let the body be pushed forward, converted into kinetic energy while properly controlling the vertical component of force.

Avoid wasting energy by over-raising the center of gravity.

Adjust the angle and direction of force.

Increase the horizontal component of ground reaction force from the normal level of 60%-65% to 70%-75%.

Significantly improves kinetic energy generation efficiency.

In addition, the duration of the ground reaction force also needs to be precisely controlled.

Too short an action time will reduce the force transmission effect.

Too long will increase energy loss.

It needs to be highly matched with the rhythm of muscle contraction.

Engage your gluteus maximus!

This is where Su Shen is the strongest.

It is also the most important point in the sprint event.

Isn’t it a coincidence that the core point of the sprint event happens to be where Su Shen’s strongest muscular talent lies.

Then.

If this is not mobilized.

I feel so sorry for Nuwa, the goddess who created the character.

Gluteus maximus exercises as you wish!

Increase your ground pushing power!

In plateau environments, the human body increases muscle contraction to adapt to low oxygen. The gluteus maximus is a hip flexor muscle that works in conjunction with the leg muscles during the push-off phase of a 100-meter sprint.

When the gluteus maximus contracts, it can effectively extend the hip joint, causing the legs to push the ground backward and downward, generating a strong vertical component of force, helping athletes obtain greater ground reaction force.

This will raise the body's center of gravity and provide support for subsequent take-off and forward movement.

Keep your body steady!
During sprinting, a stable body posture is essential to maintain the effective transfer of vertical forces.

The gluteus maximus maintains the correct position and posture of the pelvis by contraction, preventing the pelvis from tilting forward or backward excessively, keeping the body stable in the vertical direction, and ensuring that force can be efficiently transferred from the legs to the ground, thereby improving the efficiency of utilizing vertical force.

55 m.

Assist with leg swing!

During the swing phase of the 100-meter sprint, the gluteus maximus works with the other hip muscles to swing the thigh backward and forward.

Backswing.

The contraction of the gluteus maximus extends the thigh backward, storing energy for the forward swing.

Front swing.

It also helps control the swing speed and amplitude of the thigh, allowing Su Shen's legs to swing forward quickly, driving the body forward, thereby increasing the horizontal component of force.

60 m.

The buttocks generate electricity and provide propulsion!
During the leg pushing off the ground and swinging, the gluteus maximus transmits power to the trunk and lower limbs through the movement of the hip joint, generating a forward propulsion force.

In plateau areas, due to the increase in muscle strength, the gluteus maximus generates greater propulsion force, which can more effectively push the body to accelerate forward in the horizontal direction.

Increase your sprint speed!

The feeling of lightning speed!
Su Shen felt it himself.

I could clearly feel my extreme speed and that I was breaking through the limit.

fast.

Even faster.

Bang bang bang bang bang.

Conversion of gravitational potential energy and kinetic energy.

transform.

Transformation!!!

Muscle fiber recruitment and metabolic adaptation!

The low-oxygen environment at high altitudes stimulates the human neuromuscular system, prompting more gluteus maximus muscle fibers to be recruited and involved in the work.

According to the principle of motor unit recruitment, in a hypoxic state, in order to maintain the necessary exercise intensity, the nervous system will preferentially activate fast muscle fibers.

The gluteus maximus has a higher proportion of fast-twitch muscle fibers. These fibers have strong contraction force and fast contraction speed, and can generate explosive vertical force at the moment of pushing off the ground.

Su Shen has a natural advantage here.

Because he has been trained and developed scientifically since childhood, his original talents have become even more brilliant.

Fast-twitch muscle fibers.

More, higher and stronger.

Transformation!!!

Strengthening the biomechanical leverage principle!

The gluteus maximus' attachment point and lever arm structure at the hip joint enable it to exert a good leverage effect when pushing off the ground.

In plateau areas, in order to counteract the decreased athletic ability caused by hypoxia, the body will unconsciously adjust its body posture and force pattern, allowing the gluteus maximus muscle's lever arm to be more fully utilized in the ground-pushing action.

When the gluteus maximus contracts, with the hip joint as the fulcrum and the leg as the lever arm, the lever effect is amplified under the action of the reaction force of the ground, which can generate a greater vertical torque, effectively increase the vertical force, and help Su Shen achieve a higher jumping height and better flying effect.

Not bad.

But not enough!

And more!
It can be even faster!
After the biological lever is strengthened, it is the key move——

Adaptive adjustment of the gait cycle in the extreme speed zone!
At altitude, an athlete's gait cycle changes due to low oxygen.

The gluteus maximus plays an important role in this adaptation, allowing for greater horizontal displacement with limited oxygen supply.

Is the gluteus maximus mobilization excellent?

It will be the key to whether your performance is good or not.

Su Shen has already focused his energy here.

In the low-oxygen environment of the plateau, where the oxygen partial pressure is 30%-40% lower than that of the plains, the human body shortens its gait cycle to maintain athletic performance. This adaptive change stems from the coordinated regulation of the neuromuscular-metabolic system.

According to Fitts' law, hypoxia causes a decrease in the threshold for motor unit recruitment, which results in the preferential activation of type II fast-twitch fibers in the gluteus maximus. Its high contraction speed characteristics provide a basis for increasing the step frequency. Metabolomics studies have shown that under hypoxic conditions, the consumption rate of creatine phosphate reserves in gluteus maximus cells accelerates, prompting ATP regeneration to rely on the glycolysis pathway. This metabolic shift provides instantaneous energy support for rapid contraction.

Dynamic analysis showed that when the step frequency increased by 20%, the single push-off time was shortened to 0.18±0.02s. The gluteus maximus needed to complete the conversion between concentric contraction to generate propulsion and eccentric contraction to cushion the impact of landing in a shorter time, which put higher demands on its contraction rate and coordination.

That’s the first point.

Break the limit of cadence!

Keep improving!

Shorten your push!!!

How do I know how much amount I need to make?

Judge by naked eye?

Experience judgment?

Subjective judgment?

Of course not.

It requires scientific judgment.

Su Shen's approach is -

Using the latest functional near-infrared spectroscopy, this system monitoring showed that after 72 hours of plateau exposure, the activation pattern of the brain's motor cortex on the gluteus maximus muscle changed significantly.

The theory of neuroplasticity points out that hypoxic stimulation increases the excitability of spinal motor neurons, leading to a 15%-20% increase in the synchronization of gluteus maximus motor unit recruitment.

Combined with electromyography research, when the step frequency increases, the coordinated contraction pattern of the anterior and posterior bundles of the gluteus maximus shows an optimized phase difference.

The eccentric contraction strength of the toe-in during the early stage of the swing and 0-150ms after leaving the ground increased by 32%.

In the late push-off phase, the peak concentric force of the rear bundle increases by 100% from 0 to 28 ms before landing.

This precise regulation of neural control effectively reduces the energy loss of muscle contraction and achieves a balance between increased cadence and energy efficiency.

But it’s good.

This feature.

Just ask you.

If we do not rely on advanced professional instruments and fixed-point analysis systems.

How could you possibly figure that out with your own eyes or experience?
Moreover, everyone's physiological conditions are different. Most importantly, even everyone's winning situations are different each season.

If you force something to fit in,

That would only have the effect of trying to find a sword by carving a mark on the mark.

Of course, in our country, for a long time, we were just trying to find a sword by carving a mark on the boat.

If it is placed on the original timeline.

Even now in 2013, sorry, we are still following the old pattern.

Extremely rigid.

Su Shen really started to get in touch with the professional system in 2014~2015.

The team was really handed over to Randy in 2017 and 2018.

so what.

And this is just him.

If we look at the entire track and field team.

This timeline may have to be pushed back a lot.

After all, only those outstanding top athletes can receive such treatment.

Most ordinary athletes.

There are no such resources to allocate, and domestic coaches still rely on their empiricism and naked eye to make subjective judgments and decide on their training intensity and training system.

You thought that was the end of it.

Is that still called science?

This is just the beginning. If you want to do this step well, the application of science is essential, and the more you go forward, the more refined it becomes. Without the support of science, you simply cannot do it.

Do you think you are Bolt?

Even Bolt.

Among all West African black people.

Isn't he the only one?

If you want to make progress, unless you are Bolt, you have to do it the scientific way.

Study in a scientific way.

Progress in a scientific way.

If you feel it is useless, it only means that the method you are looking for is not scientific enough for you.

It is better to complete the above step before the second step.

Biomechanical compensation mechanisms and optimization of motion economy.

Based on the analysis of the multi-rigid body dynamics model, the angular displacement range of the hip joint was reduced by 12°-15°, but the gluteus maximus maintained the horizontal propulsion force by adjusting the force angle.

Biomechanical research from Su Shen's laboratory shows that in plateau sprinting, the horizontal component of the gluteus maximus contraction force increases from 48% on the plains to 55%, thanks to the dynamic optimization of its lever arm during hip flexion-extension movement.

The viscoelastic properties of the muscle-tendon unit play a key role in this process. In the plateau hypoxic environment, the stiffness of the gluteus maximus tendon increases by 8%-12%, which increases the elastic potential energy stored during rapid swinging by 20% and the elastic potential energy conversion efficiency by 18% during the ground pushing phase.

This biomechanical compensation mechanism ensures propulsive force output when the cadence increases while maintaining movement economy.

This is followed by coordinated adaptations of the neuro-muscular-skeletal system.

In the high altitude hypoxic environment, the adaptive changes of the gluteus maximus form feedback regulation with the entire motor system.

Biomechanical studies have found that an increase in cadence leads to an 18% increase in the peak vertical component of the ground reaction force. The gluteus maximus increases its contraction strength by 25% by enhancing its isometric contraction ability, maintaining the pelvic tilt angle stable at 15°±2° and avoiding loss of horizontal propulsion force due to excessive forward tilt.

At the same time, the torque generated by the contraction of the gluteus maximus is transmitted to the knee joint through the iliotibial band, forming a synergistic torque with the quadriceps femoris to ensure the stability of the lower limb swing.

This coordinated adaptation of the neuro-muscular-skeletal system is an important guarantee for adjusting the gait cycle and maintaining athletic performance in plateau environments.

Then to the adaptive regulation of the central pattern generator.

The central pattern generator, a neural network in the spinal cord that autonomously generates rhythmic movement signals, undergoes significant functional remodeling under the high-altitude hypoxic environment.

Studies have shown that hypoxic stimulation reduces the activity of γ-aminobutyric acid neurons in CPG, while enhancing the activity of glutamatergic neurons, leading to an increase in the frequency of rhythmic nerve impulses they output.

The gluteus maximus is the main motor muscle group of the lower limbs, and its motor units are directly regulated by CPG output signals.

When the cadence increases, CPG adjusts the timing of nerve impulse release, shortening the contraction/relaxation transition period of the gluteus maximus in the swing and stance phases by 12%-15%, thereby achieving synchronization with the increased cadence.

Functional magnetic resonance imaging showed that after plateau exposure, the cerebral cortex's regulatory pathways on CPG, such as the corticospinal tract, underwent plastic changes, enhancing the ability to fine-tune the movement pattern of the gluteus maximus.

Just tell me these things.

Without a powerful scientific laboratory to conduct research and analysis, can you, no matter how experienced a coach, do it on your own?

Don’t say that even the most experienced coach can’t handle it. Even the most experienced coaching team can’t handle it.

Because this has already gone beyond the scope of human empiricism.

Why does Su Shen always emphasize that the future of sprinting will be technical and scientific?

This is because the original human-centered model is becoming less and less suitable for future short-distance running. If we want to move forward, we must combine it with technological advancement.

We must make good use of scientific progress.

……

The speed is up.

It has reached the previous critical point.

But how to say it?

This time Su Shen felt...

I still have some energy left.

It's a feeling that there is still strength to be mobilized.

This is it.

So much has been done before.

Isn’t it just for now?

Utilize techniques such as conversion of gravitational potential energy into kinetic energy during sprinting.

On the plateau, forced pushes the dynamic integration of the proprioceptive feedback system of the gluteus maximus.

Mechanical coupling of the musculoskeletal system!

The mechanical coupling relationship between the gluteus maximus and the lower limb bones is particularly critical in plateau gait adjustment.

Finite element analysis shows that when the cadence increases, the peak stress on the gluteus maximus attachment points, such as the posterior ilium and the gluteal tuberosity of the femur, increases by 30%. This stress change prompts adaptive remodeling of the bones.

Studies on bone cell mechanical signal transduction have shown that under mechanical stress stimulation, the density of trabeculae at the attachment of the gluteus maximus increased by 15% and the thickness of the cortical bone increased by 8%, enhancing the mechanical bearing capacity of the bone.

I saw that the torque generated by the contraction of Su Shen's gluteus maximus was transmitted to the torso through the hip joint.

Forms a specific angle with the mechanical axis of the spine.

In the high-altitude hypoxic environment, the force transfer path can be optimized by adjusting the body's forward lean angle, usually increasing it by 5°-8°.

This allows the horizontal force generated by the gluteus maximus to be more directly converted into forward momentum.

Fluid mechanics effect!

The air density on the plateau is 20%-25% lower than that on the plains, which changes the fluid dynamics environment when the human body is moving. When Su Shen swings his legs quickly, the air resistance generated by the thigh movement driven by the gluteus maximus is reduced, but at the same time, the air's support effect on the limbs is also reduced.

To compensate for this effect, the gluteus maximus needs to increase its contraction force to maintain the stability and speed of limb swing.

For example, computational fluid dynamics simulations show that when the step frequency increases from 3.0 steps/second on a plain to 3.5 steps/second on a plateau, this 0.5 increase requires the gluteus maximus to provide an additional 12%-15% force in the swing phase to overcome the lack of air support.

To ensure that the swinging leg can swing forward quickly and land accurately.

There is also adaptive remodeling of the cytoskeleton!
Co-adaptation of the cardiovascular-muscular system!

Coming to the neuroplasticity mechanisms of the central pattern generator!
The rhythmic regulation of CPG depends on the dynamic balance of its internal neural network.

In the high-altitude hypoxic environment, hypoxia-inducible factors reshape the neural microenvironment of CPG by regulating neuronal metabolism and ion channel function.

Research from Su Shen's laboratory shows that HIF-1α activation can downregulate the expression of neuronal voltage-gated potassium channels, prolong the duration of action potentials, and lead to an increase in the frequency of nerve impulses output by CPG.

Functional connectivity analysis shows that there is cross-system coupling between CPG and the brainstem respiratory center, and hypoxia-induced hyperventilation further regulates the CPG output pattern through respiratory-motor interaction. Knowing this, you can make your gluteus maximus contraction rhythm form a specific phase relationship with the respiratory rate, and at this level, further optimize the energy allocation efficiency.

And then.

This is the core link of adaptive adjustment of the gait cycle.

Everyone knows that this is to increase the cadence and stride length in the extreme speed zone.

But how to do it?

After reaching the extreme, what else should be done to push it further?

after all.

Su Shen has reached a very high level.

He is no longer a rookie among the elite or international elites.

Push yourself further to break the limits of speed.

The solution is -

Under adaptive adjustment of the gait cycle in the extreme speed zone.

Thoroughly stimulate your gluteus maximus proprioceptors.

first step.

Activation of bidirectional regulatory networks in sensory feedback systems.

Changes in the sensitivity of muscle spindles and Golgi tendon organs involve complex molecular signaling pathways.

Under hypoxic conditions, increased levels of reactive oxygen species activate the transient receptor potential channel family, which reduces the response threshold of muscle spindle afferent fibers to mechanical stimulation.

At the same time, the downstream mitogen-activated protein kinase pathway is activated, promoting the expression of nerve growth factor and enhancing the excitability of sensory neurons.

In feedback regulation, spinal dorsal horn neurons dynamically adjust the efficiency of sensory signal transmission according to exercise intensity through presynaptic inhibition mechanisms, ensuring that the gluteus maximus can maintain precise force output control even in a fatigued state.

At this moment.

Under hypoxic environment, long noncoding RNA plays a key role in the adaptive changes of gluteus maximus muscle.

For example, hypoxia-induced lncRNA-HIF binds to HIF-1α protein, prolongs its half-life and enhances its transcriptional activity, upregulating the expression of downstream angiogenic genes by 3.2 times. MicroRNA networks are also involved in regulation.

miR-210 optimizes oxidative phosphorylation efficiency by targeting subunits of the mitochondrial electron transport chain complex.

These noncoding RNAs synergistically regulate the metabolism and contractile function of gluteus maximus at the transcriptional and post-transcriptional levels by forming a complex regulatory network.

Go one step further.

Under hypoxic stress, gluteus maximus muscle cells maintain homeostasis by activating the autophagy pathway. After inhibition of the mammalian target of rapamycin signaling pathway, autophagy-related protein complexes assemble to clear damaged mitochondria and protein aggregates.

At the same time, the dynamic balance of mitochondria changes, and the expression of mitochondrial fusion proteins is upregulated to promote mitochondrial fusion.

Enhances the assembly efficiency of respiratory chain complexes.

This autophagy-mitochondrial dynamics synergistic mechanism enables the gluteus maximus to maintain a stable mitochondrial membrane potential in a hypoxic environment, ensuring the ultimate supply of ATP required for sustained contraction.

At this time, the role of preparation and self-discipline comes into play.

Because in the high-altitude hypoxic environment, there is metabolic synergy between the liver, adipose tissue and gluteus maximus.

Under hypoxic stimulation, hepatic gluconeogenesis is enhanced, and glucose is released for muscle utilization through glucose transporter 2. Adipose tissue lipolysis is accelerated, and free fatty acids enter the gluteus maximus mitochondria for β-oxidation through carnitine palmitoyltransferase 1.

Metabolomics studies have shown that after hypoxic training, branched-chain amino acid metabolism in the gluteus maximus is enhanced, and its decomposition product α-ketoisocaproic acid can serve as an energy substrate and regulate protein synthesis.

This multi-organ metabolic synergy increases energy utilization efficiency by 25%-30%.

These are the preparations for completely opening the Speed ​​Gate.

None of these.

As an ultimate prospect player.

You will never be able to open this door.

Don't think of this as copying.

After all, in history, the top promising players except Green can be mobilized separately, but it is impossible to take care of them all in one game.

the rest.

Don't even talk about balancing both.

Even transferring them separately is difficult.

Su Shen.

This is about doing something that the ultimate prospect has never done before.

We must do things that have never been done before and will never be done again.

Want to do this.

You will feel the above.

It's all natural.

It's something that should be paid for granted.

Even more complicated.

Are willing to bear.

Gluteus maximus proprioceptors.

Start to get restless.

Adaptive changes in the gluteus maximus muscle spindle!
Muscle spindles are proprioceptors that sense changes in muscle length. In addition to being changed through training, their physiological characteristics will also change significantly in the high-altitude hypoxic environment.

Because hypoxia can increase the excitability of gamma motor neurons within muscle spindles, this is due to changes in hypoxia-induced neurotransmitter release.

Under hypoxic conditions, the amount of acetylcholine released by gamma motor neurons increases, which increases the sensitivity of muscle spindles. Studies have found that after 2-3 weeks of exposure to the plateau, the discharge frequency of muscle spindle afferent nerve fibers increased by 15%-20% compared to the plain environment.

This increased sensitivity allows the muscle spindle to more quickly and accurately sense the slight changes in the length of the gluteus maximus. When the gluteus maximus contracts or relaxes rapidly at high altitudes, the muscle spindle can promptly transmit this information to the central nervous system, providing accurate feedback for subsequent neural regulation.

Gluteus maximus muscle spindle, untied.

Then came the functional remodeling of the Golgi tendon organ in the gluteus maximus.

Golgi tendon organs mainly sense changes in muscle tension.

In addition to scientific development and training, its functions have also undergone adaptive remodeling in the high-altitude hypoxic environment.

Hypoxia leads to the accumulation of muscle metabolites such as lactic acid and carbon dioxide, which can change the chemical microenvironment around the Golgi tendon organ.

The acidic environment activates chemically sensitive ion channels on the Golgi tendon organs, lowering their threshold for response to changes in muscle tension.

In plateau conditions, when the gluteus maximus contracts to produce the same tension, the discharge start time of the afferent nerve fibers of the Golgi tendon organ is 10-15 milliseconds earlier than that in the plains, and the discharge frequency increases by 18%-25%.

This means that at high altitudes, the Golgi tendon organs can sense changes in gluteus maximus tension earlier and more strongly, thereby participating in movement control more effectively.

Golgi tendon organ, unraveled.

Proprioceptive information is transmitted from the muscle spindles and Golgi tendon organs via afferent nerve fibers to the dorsal horn of the spinal cord.

At the spinal cord level, this information undergoes an initial integration with other sensory information.

In the high altitude hypoxic environment, the excitability of spinal cord neurons changes.

Hypoxia-induced neuroplasticity strengthens the synaptic connections between spinal interneurons, especially those related to proprioceptive information processing, which leads to more efficient transmission of proprioceptive information in the spinal cord and more obvious signal amplification effect.

After a period of plateau training, the spinal cord's processing speed of gluteus maximus proprioceptive information increased by 12%-18%, enabling the spinal cord to adjust the output of motor neurons more quickly based on proprioceptive feedback and control the contraction and relaxation of the gluteus maximus.

Su Shen had already made preparations for these.

Initial integration at the spinal cord level, unravelling.

Proprioceptive information is transmitted through the spinal cord to the somatosensory and motor areas of the cerebral cortex.

In the plateau environment, the cerebral cortex's ability to process and integrate proprioceptive information is enhanced. Functional magnetic resonance imaging studies have shown that after plateau exposure, the activation of the somatosensory and motor areas of the cerebral cortex increased significantly, and the connections between neurons became tighter.

This is because hypoxia stimulates the secretion of nerve growth factors, such as brain-derived neurotrophic factor, which can promote neuronal survival, growth and synapse formation.

The cerebral cortex is able to precisely adjust the gait cycle through high-level integration of proprioceptive information from the gluteus maximus.

Higher-order integration and regulation of the cerebral cortex, unraveled.

The gushing power has been generated.

In the body, it is surging like a mighty river.

Su Shen still thinks it’s not enough.

Because he didn't want to waste the opportunity.

What a waste of good physical condition for the final warm-up.

It's got to be here.

Take it off in one go.

One hit to the ground.

Mechano-electro-chemical coupling of the musculoskeletal system!

There is multimodal signal conversion in the transmission of mechanical stimulation at the bone-muscle interface. When the gluteus maximus contraction stress exceeds the threshold, osteocyte cilia sense mechanical strain and activate Piezo1 ion channels to trigger intracellular calcium signal fluctuations. This mechanical-electrical signal conversion further triggers the Wnt/β-catenin signaling pathway, promoting osteoblast differentiation and bone matrix mineralization.

At the same time, the metabolites produced by muscle contraction diffuse into the bones through the extracellular matrix, regulating the activity of osteoclasts and forming stress-adaptive bone remodeling. Finite element simulation shows that this coupling mechanism can theoretically improve the matching degree between the trabecular arrangement direction and stress vector in the gluteus maximus attachment area by 40%.

Is it enough?
not enough! ! !
Su Shen must ensure his rapid breakthrough this time.

It will definitely succeed!!!

Cascade regulation of the neuro-endocrine-immune network!
Hypoxic stress activates the hypothalamic-pituitary-adrenal axis, increasing cortisol secretion 2-3 fold and regulating gluteus maximus metabolic gene expression through glucocorticoid receptors.

At the same time, cytokines secreted by immune cells are involved in the exercise adaptation process. TNF-α promotes the transformation of muscle fiber type to fatigue-resistant type by activating the nuclear factor κB pathway.

The bidirectional interaction between the neuroendocrine system and the immune system forms a complex regulatory network, in which the vagus nerve-mediated cholinergic anti-inflammatory pathway can regulate the activity of immune cells.

Reduce exercise-induced inflammation.

Maintain stable gluteus maximus function.

Su Shen seemed to have entered a white-hot state.

If you watch the slow motion shot of the high-speed camera afterwards, you will find that his eyes were full of brilliance at that time.

It was like flames were about to burst out of the pupils.

Ignite the energy.

Explosion all over the body!

Su Shen has buffed his body.

Superposition to the extreme.

Unlocking these technical skill systems is like gaining buffs one by one.

Keep adding more.

Keep adding more.

Keep adding more.

this time.

Is that enough?
so?

Is that enough?
I just don't believe it.

The ultimate speed gantry for the ultimate promising player.

Can you stop me this time?

Su Shen roared in his heart.

The powerful energy state inside the body has expanded to its limit.

It's not electric light anymore.

It felt like plasma was flowing inside his body.

The energy has surged to the point of being compressed into a slurry.

If this is a goal that no extremely promising athlete in history has ever been able to cross.

So this time.

Su Shen.

In perfect physical condition.

With the already full stack.

The time, place and people are favorable.

That is the triple buff of heaven, earth and man.

Start to attack the extreme speed dragon gate.

Go over.

It's the new space.

Go over.

It means the fish turns into a dragon.

The limit will be greatly increased.

From now on, the sky is high and birds can fly.

The sea is wide enough for fish to leap!
past.

Go over.

Get over there!!!

past.

You will see a new world!!!
Bang——————————

I don’t know, it’s in my mind.

Or in the body.

Or in consciousness.

Something suddenly shattered.

Su Shen only felt his whole body.

I felt relieved instantly.

The air resistance in front seemed to make way for me.

It is no longer like before, as if there were chains trapping me from moving forward at a high speed.

opened.

It worked!
The ultimate speed gantry for the ultimate promising player.

By him.

Crossed.

On the playing field.

Zhao Haohuan was stunned.

There's no way, it's still him.

He is still the closest to Su Shen.

It was only his current top speed.

To feel it.

The red figure in front.

What sudden change has occurred?

This……

This guy.

Move forward at a rapid speed.

Improved???
How fast.

It would be almost time for Lao Zhao to enter the third stage if he hadn’t activated the six-second burst.

So now.

It is just being stabilized.

It's completely overpowered.

ps: The extreme speed of the Ultimate Future players is a fatal flaw, just like a genetic chain that no one can shake.

But combining these theoretical things and demonstrating them in practical applications is probably enough.

Su Shen successfully broke the deadlock and jumped over the goal.

The road ahead is reopened.

way forward.

Restart it.

There is no longer no way out...