Unlocking the Secrets of Bacopa: How It Supports Brain Development

Unlocking the Secrets of Bacopa: How It Supports Brain Development

Development delay and Brain

GABA and autism connection

The human brain is a marvel of complexity, continuously evolving and developing throughout life. Proper brain development is essential for optimal cognitive function, memory, and overall mental health. Bacopa monnieri, commonly known as Bacopa, is an ancient herb that has been used in traditional medicine for its brain-enhancing properties. In this article, we will delve into the scientific evidence supporting how Bacopa aids in brain development.

Understanding Bacopa

Bacopa monnieri is a herb native to India and is a staple in Ayurvedic medicine. It is renowned for its adaptogenic properties, meaning it helps the body adapt to stress and promotes overall well-being. Over the years, research has focused on the brain-boosting potential of Bacopa, particularly in supporting brain development and cognitive function.

1. Neuroprotective Effects

Bacopa contains active compounds known as bacosides, which have potent neuroprotective properties. These bacosides help shield brain cells from oxidative stress and neurotoxicity, both of which can be detrimental to the developing brain. By acting as powerful antioxidants, Bacopa protects neurons from damage, fostering a conducive environment for healthy brain growth and development.

Study Link:
Title: Neuropharmacological Review of the Nootropic Herb Bacopa monnieri
Link: https://pubmed.ncbi.nlm.nih.gov/21129414/

2. Enhanced Neurotransmitter Function

Neurotransmitters are chemical messengers that facilitate communication between nerve cells (neurons) in the brain. Bacopa has been shown to influence various neurotransmitters, including acetylcholine, serotonin, and dopamine. Acetylcholine is particularly crucial for memory, learning, and cognitive processes. By modulating neurotransmitter activity, Bacopa may enhance brain development during critical periods.

Study Link:
Title: Effects of a Standardized Bacopa monnieri Extract on Cognitive Performance, Anxiety, and Depression in the Elderly
Link: https://pubmed.ncbi.nlm.nih.gov/20590480/

3. Neurogenesis Promotion

Neurogenesis, the process of forming new neurons in the brain, is vital for brain plasticity and learning. Bacopa has been linked to increased neural stem cell proliferation and differentiation, leading to the generation of new neurons. This effect could contribute to improved brain plasticity and enhanced cognitive abilities during brain development.

Study Link:
Title: Bacopa monnieri and L-deprenyl differentially enhance the activities of antioxidant enzymes and the expression of cytoprotective genes
Link: https://pubmed.ncbi.nlm.nih.gov/16621398/

4. Antioxidant and Anti-Inflammatory Actions

Bacopa’s antioxidative properties extend beyond protecting brain cells from oxidative stress. It also helps reduce inflammation in the brain, which can hinder normal brain development. By neutralizing free radicals and reducing inflammation, Bacopa supports a healthier brain environment conducive to optimal growth and development.

Study Link:
Title: Effect of standardized extract of Bacopa monnieri (Bacognize®) on cognitive functions of medical students: A six-week, randomized placebo-controlled trial
Link: https://pubmed.ncbi.nlm.nih.gov/31235759/

Conclusion

Bacopa monnieri holds great promise as a natural supplement for supporting brain development. Through its neuroprotective effects, modulation of neurotransmitters, promotion of neurogenesis, and antioxidant and anti-inflammatory actions, Bacopa fosters an environment for optimal brain growth and cognitive function. However, it’s important to note that while Bacopa shows exciting potential, further research is still needed to fully understand its precise mechanisms and long-term effects on brain development.

As with any supplement or herbal remedy, it is advisable to consult with a healthcare professional before using Bacopa, especially for pregnant women, nursing mothers, and individuals with specific health conditions. Embracing the power of Bacopa may open up new possibilities for promoting healthy brain development and unlocking the full potential of our cognitive abilities.

Alpha-GPC and Brain Development: Unleashing the Potential of a Vital Nutrient

Alpha-GPC and Brain Development: Unleashing the Potential of a Vital Nutrient

Development delay and Brain

Alpha GPC cognitive function

The human brain is a marvel of complexity, continually developing and adapting from infancy through adulthood. Nutrition plays a crucial role in supporting brain health and cognitive function, with choline being one of the essential nutrients for optimal brain development. Alpha-GPC (Alpha-glycerophosphocholine), a naturally occurring choline compound, has emerged as a promising supplement with potential benefits for brain development. In this article, we will explore in detail how Alpha-GPC aids in brain development, backed by scientific studies and research.

Understanding Alpha-GPC

Alpha-GPC is a water-soluble compound found naturally in the body and various food sources. It is known for its high bioavailability, allowing it to cross the blood-brain barrier effectively. Once in the brain, Alpha-GPC exerts its effects through several mechanisms that contribute to brain development.

1. Choline Source for Neural Connectivity

Choline is a critical nutrient that plays a fundamental role in brain development and function. As a choline donor, Alpha-GPC provides the building blocks necessary for the synthesis of acetylcholine, a neurotransmitter involved in memory, learning, and muscle control. During brain development, acetylcholine is crucial for forming neural connections and synapses, laying the foundation for optimal cognitive abilities.

Study Link:
Title: Choline: An Essential Nutrient for Public Health
Link: https://pubmed.ncbi.nlm.nih.gov/15640516/

2. Precursor to Phospholipids

Phospholipids are essential components of cell membranes, including those in the brain. They maintain cell structure and integrity, facilitate cell signaling, and protect neurons. Alpha-GPC acts as a precursor to phospholipids, ensuring an adequate supply of these vital molecules for the growing brain cells.

Study Link:
Title: Alpha-Glycerylphosphorylcholine as a Cognitive Enhancer in Rats
Link: https://pubmed.ncbi.nlm.nih.gov/16336208/

3. Neuroprotective Properties

The developing brain is susceptible to oxidative stress and neurotoxicity, which can disrupt normal developmental processes and impair cognitive function. Alpha-GPC has demonstrated neuroprotective properties, acting as a shield against these harmful effects. By preserving brain cells and neurons, Alpha-GPC promotes healthy brain development and reduces the risk of cognitive impairments.

Study Link:
Title: Alpha-Glycerylphosphorylcholine Protects Against Amyloid-Beta1-40-Induced Oxidative Stress in Rat Hippocampus
Link: https://pubmed.ncbi.nlm.nih.gov/3112552/

4. Enhanced Brain Energy Metabolism

Alpha-GPC supports brain energy metabolism by aiding in the synthesis of phospholipids and maintaining mitochondrial integrity. Mitochondria are responsible for producing adenosine triphosphate (ATP), the primary energy currency of cells. Proper energy metabolism is vital for the active and dynamic processes of brain development.

Study Link:
Title: Alpha-Glycerophosphocholine in the Mental Recovery of Cerebral Ischemic Attacks. An Italian Multicenter Clinical Trial
Link: https://pubmed.ncbi.nlm.nih.gov/3373433/

Conclusion

Alpha-GPC emerges as a promising nutrient in supporting brain development. Through its role as a choline donor, phospholipid precursor, and neuroprotective agent, Alpha-GPC contributes to neural connectivity, cellular integrity, and brain energy metabolism. This multifaceted approach makes Alpha-GPC a valuable compound in promoting healthy cognitive development and potentially improving brain function.

However, further research is warranted to fully understand its long-term effects and potential applications in brain health. As with any supplement, it is essential to consult with a healthcare professional before incorporating Alpha-GPC into any health regimen, especially for pregnant women, nursing mothers, and individuals with underlying health conditions.

Resources
Excessive Neuroinflammation in Autism Spectrum Disorders May Be Linked to GABAergic/Glutamatergic Imbalance

Excessive Neuroinflammation in Autism Spectrum Disorders May Be Linked to GABAergic/Glutamatergic Imbalance

Development delay and Brain, Methylation

Recent research into autism spectrum disorders (ASD) has indicated that an imbalance between the
neurotransmitters GABA and glutamate may be linked to excessive neuroinflammation. GABA is a
naturally-occurring inhibitory neurotransmitter, while glutamate is an excitatory neurotransmitter;
when there is an imbalance between the two, it can lead to a variety of neurological problems. This
imbalance in the GABAergic/glutamatergic system has been strongly associated with ASD, suggesting
that neuroinflammation is a key factor in the development of this disorder.

What is Neuroinflammation?

Neuroinflammation is an inflammatory response in the brain that is often caused by an immune
system imbalance. It is characterized by a high presence of pro-inflammatory cytokines in the brain,
which can lead to disruption in neuronal function and development. Neuroinflammation is thought
to be an underlying factor in many neurological disorders, including autism spectrum disorders
(ASDs).
Recent studies have suggested that neuroinflammation in ASD is due to an imbalance between
GABAergic and glutamatergic systems. GABA and glutamate are two neurotransmitters (chemical
messengers) that control how neurons communicate with each other. In ASD, the balance between
these two neurotransmitters is disrupted, leading to a state of GABA-glutamate imbalance. This
GABA-glutamate imbalance is believed to contribute to neuroinflammation in ASD and may be one of
the factors underlying the development of ASD symptoms.

What is the GABAergic/Glutamatergic System?

The GABAergic/glutamatergic system is the neurotransmission system responsible for regulating
nerve cell excitability. This system is comprised of two main neurotransmitters, Gamma-
Aminobutyric acid (GABA) and glutamate. GABA is an inhibitory neurotransmitter that reduces the
activity of nerve cells and helps maintain a state of equilibrium within the brain. Glutamate, on the
other hand, is an excitatory neurotransmitter that increases the activity of nerve cells.
An imbalance between these two neurotransmitters can lead to excessive neuronal firing in certain
brain areas, which may contribute to a range of symptoms associated with autism spectrum
disorders (ASD). Studies have found that individuals with ASD tend to have lower levels of GABA and
higher levels of glutamate than those without ASD. This gaba-glutamate imbalance can affect the
communication between neurons and lead to issues with sensory processing, social interaction,
communication, and behavior. Furthermore, recent studies suggest that this imbalance may be
linked to excessive neuroinflammation in those with ASD, further exacerbating the symptoms
associated with the disorder.

How Might an Imbalance Between GABA and Glutamate Contribute to ASD?

There is growing evidence that the GABAergic/glutamatergic system could play an important role in
autism spectrum disorder (ASD). This system, composed of two neurotransmitters, gamma-

aminobutyric acid (GABA) and glutamate, has been linked to cognitive and emotional regulation.
Neuroinflammation is one of the processes by which excessive levels of either GABA or glutamate
can contribute to ASD.

Recent research has suggested that neuroinflammation could be a major contributor to the
development of ASD. Neuroinflammation is the body’s response to injury or disease, and it involves
the activation of specialized cells and molecules which can be triggered by factors such as
environmental toxins or infections. Excessive levels of neuroinflammation can lead to a GABA-
glutamate imbalance, where one neurotransmitter is present at higher levels than the other. This
imbalance can then result in symptoms associated with ASD, such as deficits in communication and
social interaction.

Research has also shown that some individuals with ASD have a higher number of certain immune
cells called microglia, which are involved in neuroinflammatory responses. Furthermore, studies have
linked increased levels of certain inflammatory cytokines (molecules involved in inflammation) to
impaired social behaviors in individuals with ASD.
Overall, there is strong evidence to suggest that a GABA-glutamate imbalance caused by excessive
levels of neuroinflammation could contribute to the development of ASD. It is still not known exactly
how this imbalance occurs, but more research is needed to further explore this connection and its
potential implications for those affected by autism spectrum disorder.

How GABA and Glutamate affect glutathione levels

How GABA and Glutamate affect glutathione levels

Detoxification, Development delay and Brain, Methylation

GABA and autism connection

Gaba and glutamate are two neurotransmitters in the brain that can affect glutathione levels. Glutathione is a powerful antioxidant that helps to protect cells from damage. It also plays an important role in many metabolic processes, such as detoxification and energy production.

What is Glutamate

What is GABA

GABA and Glutamate production

How GABA and Glutamate affect Glutathione levels

How can we rebalance the GABA-Glutamate level?

What is Glutamate?

Glutamate is an amino acid that acts as an excitatory neurotransmitter in the brain and nervous system. It is the most abundant neurotransmitter in the brain, and it plays a crucial role in many brain functions such as learning, memory, and brain development.

Glutamate is released from the presynaptic neuron when a nerve impulse reaches the synapse (the junction between two nerve cells). It binds to receptors on the postsynaptic neuron, which then triggers an electrical impulse in the postsynaptic neuron. This process is called synaptic transmission and is the main communication mechanism between nerve cells in the brain and nervous system.
Glutamate also forms new memories by strengthening connections between neurons, a process called Long-term potentiation (LTP).

However, too much Glutamate in the brain can be toxic to neurons and cause excitotoxicity, which impacts the development of several neurological disorders such as stroke, traumatic brain injury, and neurodegenerative diseases like Alzheimer’s and Parkinson’s. Therefore, it’s important to maintain the balance between Glutamate and other neurotransmitters, such as GABA (gamma-aminobutyric acid), which is an inhibitory neurotransmitter that counters the excitatory effects of Glutamate.

What is GABA?

GABA (gamma-aminobutyric acid) is an amino acid that acts as an inhibitory neurotransmitter in the brain and nervous system. This means that it helps to reduce the activity of neurons in the brain, helping to regulate mood, anxiety, and sleep.

When a nerve impulse reaches the synapse (the junction between two nerve cells), GABA is released from the presynaptic neuron and binds to receptors on the postsynaptic neuron. This binding leads to the opening of chloride ion channels and causes the postsynaptic neuron to become less likely to fire an action potential. This process is called synaptic inhibition, and it helps to balance the activity of excitatory neurotransmitters like Glutamate and prevent overstimulation of the neurons.

GABA is synthesized in the brain from Glutamic acid, the most abundant neurotransmitter in the brain, by the enzyme Glutamic acid decarboxylase (GAD) through a process called decarboxylation. This process requires the presence of pyridoxal phosphate (vitamin B6) as a cofactor.

Low levels of GABA have been linked to several neurological disorders, such as anxiety, depression, insomnia, seizures, and ASD. The balance between GABA and other neurotransmitters, such as Glutamate, is crucial for normal brain function, and an imbalance can lead to neurological disorders.

GABA and Glutamate production

GABA and Glutamate are both synthesized from the same precursor molecule, Glutamic acid (Glutamate).
As mentioned before, the synthesis of GABA begins with the conversion of glutamic acid to glutamic acid decarboxylase (GAD) by the enzyme glutamate decarboxylase. GAD then catalyzes the decarboxylation of glutamic acid to form GABA. This process requires the presence of pyridoxal phosphate (vitamin B6) as a cofactor. So GAD enzyme breaks down Glutamate into GABA, which keeps GABA levels high.

On the other hand, the synthesis of Glutamate starts with the conversion of alpha-ketoglutarate, a metabolite of the citric acid cycle, to Glutamate by the enzyme Glutamate dehydrogenase. This process requires the presence of NAD+ as a cofactor.
It’s worth noting that while GABA is synthesized from Glutamic acid, the majority of Glutamic acid in the brain comes from dietary sources or from the conversion of other amino acids, not from GABA.

Both GABA and Glutamate are then stored in vesicles in the presynaptic neuron, ready to be released into the synapse when an electrical impulse reaches the neuron. The amount of GABA and Glutamate released, and the activity of the receptors they bind are regulated by a complex interplay of genetic, environmental, and epigenetic factors, which can affect the balance between the two neurotransmitters and their effects on the brain and nervous system.

In a healthy individual, there is a balance between GABA and Glutamate in the brain. However, if this balance is disrupted, it can lead to symptoms such as anxiety, depression, insomnia, headaches, seizures, and even Alzheimer’s disease, and some research shows GABA-Glutamate imbalance in children with autism.

It is important to note that GABA and Glutamate also play a role in regulating glutathione levels. Glutathione is an antioxidant that helps protect cells from damage caused by free radicals. It also helps to detoxify the body and plays an important role in keeping our immune system healthy. GABA and Glutamate help keep us healthy and functioning optimally by regulating glutathione levels.

How GABA and Glutamate affect Glutathione levels

So Glutathione is a powerful antioxidant that helps to protect cells from damage. It also plays an important role in many metabolic processes, such as detoxification and energy production.

Studies have found that GABA, which is an inhibitory neurotransmitter, can decrease glutathione levels, while Glutamate, which is an excitatory neurotransmitter, can increase them. The balance between GABA and Glutamate is thought to be important for maintaining healthy levels of Glutathione.

One study found that taking a GABA supplement was associated with lower levels of Glutathione. Increasing GABA activity may reduce Glutathione levels. On the other hand, increased glutamate activity has been linked to higher Glutathione levels.
It is important to keep in mind that there may be other factors that influence Glutathione levels.

How can we rebalance the GABA-Glutamate level?

Maintaining the right balance between GABA and Glutamate is essential for optimal health. It is important for normal brain function, and an imbalance can lead to neurological disorders such as anxiety and depression. Here are some ways to help maintain GABA-Glutamate balance:

Diet

Eating a diet rich in nutrients that support brain health, such as omega-3 fatty acids, antioxidants, and B vitamins, can help to balance GABA and Glutamate.

Exercise

Regular exercise can increase the levels of GABA in the brain, which can help to reduce anxiety and improve mood.

Stress Management

Chronic stress can disrupt the balance between GABA and glutamate, leading to anxiety and depression. Therefore, managing stress through techniques such as meditation, yoga, or deep breathing can help to restore this balance.

Sleep

Getting enough quality sleep is important for maintaining the balance between GABA and Glutamate. Sleep deprivation can result from an imbalance between the two neurotransmitters, leading to anxiety, depression, and other mood-related disorders.

 

Dietary supplements that can restore GABA-Glutamate balance

Some supplements, such as Phenibut, Picamilon, ashwagandha, Theanine, etc., can help to balance GABA and glutamate levels.

Phenibut:

A derivative of GABA that can cross the blood-brain barrier and increase GABA levels in the brain.

Picamilon:

It is a combination of GABA and niacin that can increase GABA levels in the brain.

Ashwagandha:

An adaptogenic herb that can reduce anxiety and stress by regulating the balance between GABA and glutamate.

Theanine:

Theanine is an amino acid found in green tea that can increase GABA levels and reduce glutamate levels in the brain. This precursor of Glutamate appears to lower glutamate activity in the brain by blocking receptors while also boosting GABA levels. It’s found naturally in tea and also is available as a supplement.

Magnesium:

Magnesium is an essential mineral for maintaining healthy GABA-Glutamate levels. It works by helping to regulate the receptors that control the flow of these neurotransmitters. Magnesium can act as a cofactor for enzymes that are involved in neurotransmitter synthesis and release.

Inositol:

A carbohydrate that is used as a mood stabilizer and can help to balance the levels of neurotransmitters such as GABA and Glutamate in the brain

Melatonin:

A hormone involved in regulating the sleep-wake cycle, it has been found to have some effects on regulating GABA and Glutamate balance.

5-HTP:

5-HTP is a natural supplement derived from the seeds of an African plant. It has been shown to increase serotonin levels, which helps balance GABA and glutamate levels in the brain.

N-Acetylcysteine (NAC):

NAC is an amino acid supplement that is known to boost glutathione levels. It also helps to regulate GABA-Glutamate balance in the brain.

Valerian Root Extract:

The valerian root extract has been used for centuries to treat anxiety and insomnia. It works by calming down overactive nerve cells, which helps to restore GABA-Glutamate balance in the brain.

Glutamine:

Your body converts this amino acid into Glutamate. Glutamine is available in supplement form and is present in meat, fish, eggs, dairy, wheat, and some vegetables.

Taurine:

This amino acid has been shown in rodents to alter both GABA and Glutamate brain levels. You can take it in supplement form and get it naturally in meat and seafood.

These dietary supplements can help to restore the balance between GABA and Glutamate in the brain, but it’s always best to consult your doctor before starting any new supplement regimen.

GABA supplementation is not the best way to balance GABA-Glutamate levels because it can have an overstimulating effect, and unused GABA will be reconverted into glutamine, which is then converted back into Glutamate through a so-called GABA shunt metabolic pathway.

Related articles:

Glutamate and Autism Spectrum Disorder: What’s the Link?
Glutathione Redox Imbalance Linked to Autism Spectrum Disorder
Oxidative Stress May Be Linked to Autism
Glutathione
The glutathione precursor
Resources
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  5. Bulley S, Shen W. Reciprocal regulation between taurine and glutamate response via Ca2+- dependent pathways in retinal third-order neuronsJ Biomed Sci. 2010;17(Suppl 1):S5-. doi:10.1186/1423-0127-17-S1-S5
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Delacato method: with movement for intellectual development

Delacato method: with movement for intellectual development

Development delay and Brain

Carl-Henry Delacato method

According to the theory developed by Philadelphia neurologist Carl Henry Delacato and his team, there is a close connection between movement and the development of the nervous system, and intellectual development. So if the child does not have a way to practice some form of movement, it must be replaced later for proper brain development.

According to the theory, individual development follows the path of stock development, so the child copies the development process that took place when he became a human in his first years.

There is a close connection between movement and the maturation of the nervous system. If the child did not have time to practice a form of movement – either because he missed it or because the next step followed too soon, for example he started walking very early and therefore did not climb for long enough – this affects later development and even causes learning difficulties and can also cause behavior.

According to the method, the child relives an earlier period of life through movement, thus bringing in your backlog.

Delacato method can be used for intellectual development?

  • Delayed/defective/stuttering speech development
  • Speech error
  • Dyslexia/dysgraphia
  • Attention deficit disorder
  • Mild intellectual disability
  • Clumsy movement
  • Poor orientation skills
  • Integration problems

How does the treatment take place?

According to Delacato, elementary movements – crawling, climbing, walking, swimming – reveal the development of each area of ​​the nervous system. After a condition assessment, the child is given a set of 8-10 exercises, which must be repeated at home for 20-30 minutes every day. You only have to appear at one control examination a month, when you will receive a new set of exercises taking into account your progress.

The tasks develop balance, spatial perception and fine movement.

It is becoming more and more common for specialists who mainly deal with large groups to visit kindergartens as well. In such cases, 90-minute classes are held for groups of 4-5 people.

Children and young people between the ages of 5 and 16 can take part in the therapy. Since the goal of the development is to practice the missed forms of movement,teenagers do the same exercises that preschoolers do: crawling, climbing, balancing, allowing their brains and nervous systems to acquire skills that were missed in the first period.

Let's have some exercise

Check out some brain developing exercises in the related articles:

Passive exercises for children with developmental delay or brain injury

Exercises for brain and intellectual development Part 1

 

Movement developmental milestones: What should you pay attention to?

Movement developmental milestones: What should you pay attention to?

Development delay and Brain

development milestones

Children grow and develop at their own pace. This is a fact that a parent must be able to accept, just like the fact that their child may start walking or talking later. If your child does not reach certain developmental milestones, it is recommended to visit a specialist. Which milestones should you focus on?

There are children who, in terms of development, show almost a textbook example and reach each milestone on a daily basis. Then there are children who surpass their peers in everything, and there are those who develop at a slower pace , but still within the tolerance limit. When should you start worrying?

At the age of 0 - 4 months

Babies grow very quickly in the first months after birth, so parents can witness changes on a daily basis. A healthy newborn gains 140-200 grams in the first week and grows 1-2.5 cm per month. Children literally grow before our eyes and learn new skills at the same time. They must reach a certain level of development in the first four months of their lives . If you notice any of the following symptoms during this period, see your pediatrician as soon as possible, as they may indicate a developmental or other abnormality:

  • squeals
  • does not pay attention to loud noises
  • he doesn’t look at his hands
  • does not follow moving objects with his eyes
  • does not grab objects
  • he does not smile or laugh at the people around him
  • he can’t keep his head
  • not goofy and/or imitate sounds
  • does not put objects in his mouth
  • does not strain its paws when they touch a solid surface

At the age of 5 – 7 months

As the baby grows, its abilities and skills also develop. The five- to seven-month-old baby smiles, laughs, is excited . He grabs different objects, tastes them, snorts and makes noise. His world is expanding and he is discovering more and more of it every day. As with the previous one, there are defining milestones in this period , so be aware if you experience the following symptoms:

  • his posture is stiff, his muscles tense
  • his muscles are relaxed, with a rag doll posture
  • he does not hold his head, his head leans back even in a sitting position
  • he only reaches for the objects with one hand
  • rejects babysitting
  • it is not attached to the person taking care of it
  • he is sensitive to light, his eyes water
  • he finds it difficult to put his hand in his mouth
  • it does not turn over in the fifth month
  • he can’t even sit with help until the sixth month
  • you don’t laugh or make a sound until the sixth month

At the age of 8 – 12 months

When they light the first candle on the birthday cake, they most likely already have a ready-made personality at home. The past months have brought physical, mental, social and emotional changes in the baby’s life, and in terms of development, further milestones lie ahead. Around 75% of children achieve these in a certain period. Watch for the following symptoms:

  • does not climb or does not climb regularly, e.g. pulls one side
  • unable to stand even with support
  • does not search for objects hidden in plain sight
  • he hasn’t said the first word yet
  • does not gesticulate, e.g. he does not shake his head at the answer “no”.
  • does not point to pictures or objects

Up to 2 years old

Intensive development also takes place during childhood. At the age of two, the majority of children are walking, talking, jumping, running … a little one is simply everywhere. During this very active period, many parents notice when something is wrong with their child. Why do not you speak? Why doesn’t he come? Why don’t you play the games? If you notice any of the following symptoms, do not hesitate and notify your child’s doctor:

  • knows and uses less than 15 words
  • does not use two-word sentences
  • does not imitate words, sounds or movements
  • unable to follow simple instructions (not to be confused with disobedience)
  • cannot push wheeled toys
  • It does not go until the age of 18 months
  • even if you walk, you don’t use all parts of your foot (ie from toe to heel)

At the age of 3

The time flew by in a flash and it has now dwindled to three years. If your child has a developmental disorder , you’ve probably already discovered it, but there are still symptoms that cause concern:

  • often falls and cannot climb stairs
  • drools continuously and/or his speech is unintelligible
  • cannot use more than 4 cubes when building a tower
  • cannot manipulate small objects
  • cannot draw a circle
  • unable to communicate in short sentences
  • he is not interested in group play, he does not participate in it
  • does not understand simple instructions
  • no longer interested in children
  • does not maintain eye contact
  • shows little interest in games

A parent knows their child best. He is the best able to assess his development and follow the progression of his behavior and skills. We always emphasize that comparison with peers is inappropriate because children develop at their own pace, but this does not mean that the child should not be monitored. If you feel that everything is not right, or if you have noticed one of the symptoms mentioned above , contact a specialist who will order the necessary tests.

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