Unconditioned and conditioned reflexes.

An element of higher nervous activity is a conditioned reflex. The path of any reflex forms a kind of arc, consisting of three main parts. The first part of this arc, which includes the receptor, sensory nerve and brain cell, is called the analyzer. This part perceives and distinguishes the entire complex of substances entering the body. various influences from outside.

The cerebral cortex (according to Pavlov) is a collection of the brain ends of various analyzers. Stimuli from the external world arrive here, as well as impulses from the internal environment of the body, which causes the formation of numerous foci of excitation in the cortex, which, as a result of induction, cause points of inhibition. Thus, a kind of mosaic arises, consisting of alternating points of excitation and inhibition. This is accompanied by the formation of numerous conditioned connections (reflexes), both positive and negative. As a result, a certain functional dynamic system is formed conditioned reflexes, which is the physiological basis of the psyche.

Two main mechanisms carry out higher nervous activity: conditioned reflexes and analyzers.

Each animal organism can exist only if it is constantly balanced (interacts) with the external environment. This interaction is carried out through certain connections (reflexes). I.P. Pavlov identified constant connections, or unconditioned reflexes. An animal or a person will be born with these connections - these are ready-made, constant, stereotypical reflexes. Unconditioned reflexes, such as the reflex for urination, defecation, sucking reflex in a newborn, salivation, are various forms of simple defensive reactions. Such reactions are constriction of the pupil to light, squinting of the eyelid, withdrawal of the hand during sudden irritation, etc. Complex unconditioned reflexes in humans include instincts: food, sexual, orientation, parental, etc. Both simple and complex unconditioned reflexes are innate mechanisms; they operate even at the lowest levels of development of the animal world. So, for example, the weaving of a web by a spider, the construction of honeycombs by bees, the nesting of birds, sexual desire - all these acts do not arise as a result of individual experience or learning, but are innate mechanisms.

However, the complex interaction of animals and humans with the environment requires the activity of a more complex mechanism.

In the process of adaptation to living conditions, another type of connections with the external environment is formed in the cerebral cortex - temporary connections, or conditioned reflexes. A conditioned reflex, according to Pavlov, is an acquired reflex, developed under certain conditions, and is subject to fluctuations. If not reinforced, it can weaken and lose its direction. Therefore, these conditioned reflexes are called temporary connections.

The main conditions for the formation of a conditioned reflex in its elementary form in animals are, firstly, the combination of a conditioned stimulus with unconditioned reinforcement and, secondly, the conditioned stimulus preceding the action of the unconditioned reflex. Conditioned reflexes are developed on the basis of unconditioned or on the basis of well-developed conditioned reflexes. In this case, they are called conditioned or conditioned reflexes of the second order. The material basis of unconditioned reflexes is the lower levels of the brain, as well as the spinal cord. Conditioned reflexes in higher animals and humans are formed in the cerebral cortex. Of course, in every nervous act it is impossible to clearly distinguish between the actions of unconditioned and conditioned reflexes: undoubtedly, they represent a system, although the nature of their formation is different. The conditioned reflex, being generalized at first, is then refined and differentiated. Conditioned reflexes as neurodynamic formations enter into certain functional relationships with each other, forming various functional systems, and are thus the physiological basis of thinking,

knowledge, skills, labor abilities.

To understand the mechanism of formation of a conditioned reflex in its elementary form in a dog, the well-known experience of I.P. Pavlov and his students (Fig. 56).

The essence of the experience is as follows. It is known that during the act of feeding, animals (in particular dogs) begin to secrete saliva and gastric juice. These are natural manifestations of the unconditioned food reflex. In the same way, when acid is poured into a dog’s mouth, saliva is released abundantly, washing away acid particles that irritate it from the mucous membranes of the mouth. This is also a natural manifestation of the defensive reflex, which in this case occurs through the salivary center in the medulla oblongata. However, under certain conditions, it is possible to force a dog to salivate to an indifferent stimulus, for example, the light of a light bulb, the sound of a horn, a musical tone, etc. To do this, before giving the dog food, light a lamp or ring a bell. If you combine this technique one or several times, and then use only one conditioned stimulus, without accompanying it with food, you can cause the dog to salivate in response to the action of an indifferent stimulus. What explains this? In the dog’s brain, during the period of action of a conditioned and unconditioned stimulus (light and food), certain areas of the brain come into a state of excitation, in particular the visual center and the center of the salivary gland (in the medulla oblongata). The food center, which is in a state of excitation, forms an excitation point in the cortex as a cortical representation of the center of the unconditioned reflex. Repeated combination of indifferent and unconditioned stimuli leads to the formation of an easier, “trodden” path. Between these points of excitation a chain is formed in which a number of irritated points are closed. In the future, it is enough to irritate only one link in a closed chain, in particular the visual center, and the entire developed connection will be activated, which will be accompanied by a secretory effect. Thus, a new connection was established in the dog’s brain - a conditioned reflex. The arc of this reflex closes between the cortical foci of excitation that arise as a result of the action of an indifferent stimulus and the cortical representations of the centers of unconditioned reflexes. However, this connection is temporary. Experiments have shown that for some time the dog will salivate only to the action of a conditioned stimulus (light, sound, etc.), but soon this reaction will stop. This will indicate that the connection has faded; True, it does not disappear without a trace, but only slows down. It can be restored again by combining feeding with the action of a conditioned stimulus; again it is possible to obtain salivation only in response to the action of light. This experience is elementary, but it is of fundamental importance.

The point is that the reflex mechanism is the main physiological mechanism in the brain not only of animals, but also of humans. However, the ways of formation of conditioned reflexes in animals and humans are not the same. The fact is that the formation of conditioned reflexes in humans is regulated by a special, uniquely human, second signaling system, which does not exist in the brain even of higher animals. The real expression of this second signaling system is the word, speech. Hence, the mechanical transfer of all laws obtained in animals to explain all higher nervous activity in humans will not be justified. I.P. Pavlov suggested observing “the greatest caution” in this matter. However, in general view the reflex principle and a number of basic laws of the higher nervous activity of animals retain their significance for humans.

Students of I.P. Pavlova N.I. Krasnogorsky, A.G. Ivanov - Smolensky, N.I. Protopopov and others did a lot of research on conditioned reflexes in people, in particular in children. Therefore, material has now accumulated that allows us to make an assumption about the characteristics of higher nervous activity in various acts of behavior. For example, in the second signaling system, conditioned connections can be formed quickly and more firmly held in the cerebral cortex.

Let’s take for example a process that is close to us, such as teaching children to read and write. Previously, it was assumed that the basis of literacy acquisition (learning to read and write) was the development of special reading and writing centers. Now science denies the existence in the cerebral cortex of any local areas, anatomical centers, as if specialized in the area of ​​these functions. In the brains of people who have not mastered literacy, such centers do not naturally exist. However, how do these skills develop? What are the functional mechanisms of such completely new and real manifestations in the mental activity of a child who has mastered literacy? This is where the most correct idea would be that the physiological mechanism of literacy skills is the neural connections that form specialized systems of conditioned reflexes. These connections are not inherent in nature; they are formed as a result of the interaction of the student’s nervous system with the external environment. In this case, such an environment will be a classroom - a literacy lesson. The teacher, starting to teach literacy, shows the students on the appropriate tables or writes individual letters on the board, and the students copy them in their notebooks. The teacher not only shows letters (visual perception), but also pronounces certain sounds (auditory perception). As is known, writing is carried out by a certain movement of the hand, which is associated with the activity of the motor-kinesthetic analyzer. When reading, there is also a movement of the eyeball, which moves in the direction of the lines readable text. Thus, during the period of learning to read and write, the child’s cerebral cortex receives numerous irritations signaling the optical, acoustic and motor appearance of letters. This whole mass of irritation leaves nerve traces in the cortex, which are gradually balanced, reinforced by the teacher’s speech and one’s own orally student. As a result, a specialized system of conditional connections is formed, reflecting sound-letters and their combinations in various verbal complexes. This system - a dynamic stereotype - is the physiological basis of school literacy skills. It can be assumed that the formation of various labor skills is a consequence of the formation of neural connections that arise in the process of learning skills - through vision, hearing, tactile and motor receptors. At the same time, one must keep in mind the importance of innate inclinations, on which the nature and results of the development of a particular ability depend. All these connections, arising as a result of nervous stimulation, enter into complex relationships and form functional-dynamic systems, which are also the physiological basis of labor skills.

As is known from elementary laboratory experiments, a conditioned reflex that is not reinforced by food fades away, but does not disappear completely. We see something similar in people's lives. There are known facts when a person who learned to read and write, but then, due to life circumstances, did not have to deal with a book, largely lost the literacy skills he had once acquired. Who does not know such facts when the acquired skill in the field of theoretical knowledge or work skills, not supported by systematic work, is weakened. However, it does not disappear completely, and a person who has studied this or that skill, but then leaves it for a long period of time, only feels very insecure at first if he again has to return to his previous profession. However, it will relatively quickly restore the lost quality. The same can be said about people who once studied a foreign language, but then completely forgot it due to lack of practice; undoubtedly, it is easier for such a person, with appropriate practice, to regain mastery of the language than for another who will study new language for the first time.

All this suggests that traces of past irritations remain in the cerebral cortex, but, not reinforced by exercise, they fade away (inhibited).

Analyzers

By analyzers we mean formations that carry out knowledge of the external and internal environment of the body. These are, first of all, taste, skin, and olfactory analyzers. Some of them are called distant (visual, auditory, olfactory) because they can perceive stimuli at a distance. The internal environment of the body also sends constant impulses to the cerebral cortex.

1-7 – receptors (visual, auditory, skin, olfactory, gustatory, motor system, internal organs). I – area of ​​the spinal cord or medulla oblongata where afferent fibers enter (A); impulses from which are transmitted to the neurons located here, forming the ascending pathways; the axons of the latter go to the area of ​​the optic hillocks (II); the axons of the nerve cells of the visual thalamus ascend into the cerebral cortex (III). At the top (III) the location of the nuclear parts of the cortical sections of various analyzers is outlined (for the internal, gustatory and olfactory analyzers, this location has not yet been precisely established); The scattered cells of each analyzer scattered throughout the cortex are also indicated (according to Bykov)

One of these analyzers is the motor analyzer, which receives impulses from skeletal muscles, joints, ligaments and reports to the cortex about the nature and direction of movement. There are other internal analyzers - interoceptors, which signal to the cortex about the state of the internal organs.

Each analyzer consists of three parts (Fig. 57). The peripheral end, i.e. receptor directly facing the external environment. These are the retina of the eye, the cochlear apparatus of the ear, sensitive devices of the skin, etc., which connect through the conducting nerves to the brain end, i.e. specific area of ​​the cerebral cortex. Hence, the occipital cortex is the cerebral end of the visual, the temporal – the auditory, the parietal – the cutaneous and muscular-articular analyzers, etc. In turn, the cerebral end, already in the cerebral cortex, is divided into a nucleus, where the most subtle analysis and synthesis of certain stimuli is carried out, and secondary elements located around the main nucleus and representing the analyzer periphery. The boundaries of these secondary elements between individual analyzers are fuzzy and overlap. In the analyzer periphery, similar analysis and synthesis are carried out only in the most elementary form. The motor area of ​​the cortex is the same analyzer of the skeletal-motor energy of the body, but its peripheral end faces the internal environment of the body. It is characteristic that the analyzing apparatus acts as an integral formation. Thus, the cortex, including numerous analyzers, itself is a grandiose analyzer of the external world and the internal environment of the body. Irritations entering certain cells of the cortex through the peripheral ends of the analyzers produce excitation in the corresponding cellular elements, which is associated with the formation of temporary nerve connections - conditioned reflexes.

Excitation and inhibition of nervous processes

The formation of conditioned reflexes is possible only when the cerebral cortex is in an active state. This activity is determined by the occurrence of basic nervous processes in the cortex - excitation and inhibition.

Excitation is an active process that occurs in the cellular elements of the cortex when it is exposed to certain stimuli from the external and internal environment through analyzers. The process of excitation is accompanied by a special state of nerve cells in one or another area of ​​the cortex, which is associated with the active activity of coupling apparatuses (synapses) and the release chemicals(mediators) such as acetylcholine. In the area where foci of excitation occur, increased formation of nerve connections occurs - here a so-called active working field is formed.

Braking(detention) is also not a passive, but an active process. This process seems to forcibly restrain excitement. Braking is characterized to varying degrees intensity. I.P. Pavlov attached great value the inhibitory process, which regulates the activity of excitation, “holds it in its fist.” He identified and studied several types, or forms, of the inhibitory process.

External inhibition is an innate mechanism, which is based on unconditioned reflexes, acts immediately (from the spot) and can suppress conditioned reflex activity. An example illustrating the effect of external inhibition was a fact, not uncommon in the laboratory, when the established conditioned reflex activity in dogs in response to the action of a conditioned stimulus (for example, salivation towards light) suddenly stopped as a result of some extraneous strong sounds, the appearance of a new face, etc. d. The indicative unconditioned reflex to novelty that arose in the dog inhibited the course of the developed conditioned reflex. In people's lives, we can often encounter similar facts, when intense mental activity associated with the performance of a particular work may be disrupted due to the appearance of some extra stimuli, for example, the appearance of new faces, loud conversation, some sudden noises and etc. External inhibition is called fading, because if the action of external stimuli is repeated many times, then the animal already “gets used” to them and they lose their inhibitory effect. These facts are well known in human practice. So, for example, some people get used to working in a difficult environment, where there are many external stimuli (work in noisy workshops, work as cashiers in large stores, etc.), causing the newcomer to feel confused.

Internal inhibition is an acquired mechanism based on the action of conditioned reflexes. It is formed in the process of life, education, work. This type of active inhibition is inherent only in the cerebral cortex. Internal inhibition has a twofold character. During the day, when the cerebral cortex is active, it is directly involved in the regulation of the excitatory process, is fractional in nature and, mixing with foci of excitation, forms the basis of the physiological activity of the brain. At night, this same inhibition radiates through the cerebral cortex and causes sleep. I.P. Pavlov in his work “Sleep and internal inhibition are the same process” emphasized this feature of internal inhibition, which, participating in the active work of the brain during the day, delays the activity of individual cells, and at night, spreading, irradiating throughout the cortex, causes inhibition of the entire cerebral cortex , which determines the development of physiological normal sleep.

Internal inhibition, in turn, is divided into extinction, delayed and differentiation. In well-known experiments on dogs, the mechanism of extinctive inhibition causes a weakening of the effect of a developed conditioned reflex when it is reinforced. However, the reflex does not disappear completely; it can reappear after some time and is especially easy with appropriate reinforcement, for example, food.

In humans, the process of forgetting is caused by a certain physiological mechanism - extinctive inhibition. This type of inhibition is very significant, since the inhibition of unnecessary at the moment connections contribute to the emergence of new ones. Thus, the desired sequence is created. If all formed connections, both old and new, were at the same optimal level, then rational mental activity would be impossible.

Delayed inhibition is caused by a change in the order of stimuli. Typically, in experience, a conditioned stimulus (light, sound, etc.) somewhat precedes an unconditioned stimulus, such as food. If you leave the conditioned stimulus aside for some time, i.e. lengthen the time of its action before giving the unconditioned stimulus (food), then as a result of such a change in the regime, the conditioned salivary reaction to light will be delayed by approximately the time for which the conditioned stimulus was left.

What causes the delay in the appearance of a conditioned reaction and the development of delay inhibition? The mechanism of delayed inhibition underlies such properties of human behavior as endurance, the ability to restrain one or another type of mental reactions that are inappropriate in the sense of reasonable behavior.

Differential inhibition is extremely important in the functioning of the cerebral cortex. This inhibition can dissect conditional connections down to the smallest detail. Thus, dogs developed a conditioned salivary reflex to 1/4 of a musical tone, which was reinforced with food. When they tried to give 1/8 of the musical tone (the difference in acoustic terms is extremely insignificant), the dog did not salivate. Undoubtedly, in the complex and subtle processes of human mental and speech activity, which have chains of conditioned reflexes as their physiological basis, all types of cortical inhibition are of great importance, and among them, differentiation should be especially emphasized. The development of the finest differentiations of the conditioned reflex determines the formation of higher forms of mental activity - logical thinking, articulate speech and complex work skills.

Protective (extraordinary) inhibition. Internal inhibition has various forms of manifestation. During the day it is fractional in nature and, mixing with foci of excitation, takes an active part in the activity of the cerebral cortex. At night, irradiating, it causes diffuse inhibition - sleep. Sometimes the cortex can be exposed to extremely strong stimuli, when the cells work to the limit and their further intense activity can lead to their complete exhaustion and even death. In such cases, it is advisable to turn off weakened and exhausted cells from work. This role is played by a special biological reaction of the nerve cells of the cortex, expressed in the development of an inhibitory process in those areas of the cortex whose cells have been weakened by super-strong stimuli. This type of active inhibition is called healing-protective or transcendental and is predominantly innate in nature. During the period when certain areas of the cortex are covered by extreme protective inhibition, weakened cells are switched off from active activity, and restoration processes occur in them. As the diseased areas normalize, the inhibition is removed, and those functions that were localized in these areas of the cortex can be restored. The concept of protective inhibition created by I.P. Pavlov, explains the mechanism of a number of complex disorders that occur in various nervous and mental diseases.

“We are talking about inhibition, which protects the cells of the cerebral cortex from the danger of further damage, or even death, and prevents the serious threat that arises when the cells are overexcited, in cases where they are forced to perform impossible tasks, in catastrophic situations, in exhaustion and weakening them under the influence of various factors. In these cases, inhibition occurs not in order to coordinate the activity of the cells of this higher part of the nervous system, but in order to protect and protect them" (E.A. Asratyan, 1951).

In cases observed in the practice of defectologists, such causative factors are toxic processes (neuroinfections) or skull injuries that cause weakening of nerve cells due to their exhaustion. A weakened nervous system is favorable soil for the development of protective inhibition in it. “Such a nervous system,” wrote I.P. Pavlov, “when encountering difficulties... or after unbearable excitement inevitably goes into a state of exhaustion. And exhaustion is one of the most important physiological impulses for the emergence of an inhibitory process as a protective process.”

Disciples and followers of I.P. Pavlova – A.G. Ivanov-Smolensky, E.A. Asratyan, A.O. Dolin, S.N. Davydenko, E.A. Popov and others attached great importance to further scientific developments related to clarifying the role of healing and protective inhibition in various forms of nervous pathology, first noted by I.P. Pavlov in the physiological analysis of schizophrenia and some other neuropsychiatric diseases.

Based on a number of experimental works carried out in his laboratories, E.A. Asratyan formulated three main provisions characterizing the significance of healing-protective inhibition as a protective reaction of nervous tissue under various harmful influences:

1) healing-protective inhibition belongs to the category of universal coordination properties of all nervous elements, to the category of general biological properties of all excitable tissues;

2) the process of protective inhibition plays the role of a healing factor not only in the cerebral cortex, but throughout the entire central nervous system;

3) the process of protective inhibition plays this role not only in functional, but also in organic lesions of the nervous system.

The concept of the role of healing-protective inhibition is particularly fruitful for the clinical and physiological analysis of various forms of nervous pathology. This concept makes it possible to more clearly imagine some complex clinical symptom complexes, the nature of which long time was a mystery.

Undoubtedly, the role of protective-healing inhibition in the complex system of brain compensation is great. It is one of the active physiological components that contribute to the development of compensatory processes.

The duration of the existence of healing-protective inhibition in individual areas of the cortex in the residual stage of the disease, apparently, can have different periods. In some cases it does not last long. This mainly depends on the ability of the affected cortical elements to recover. E.A. Asratyan points out that in such cases a peculiar combination of pathology and physiology occurs. In fact, on the one hand, the protective inhibitory process is healing, since turning off a group of cells from active work gives them the opportunity to “heal their wounds.” At the same time, the loss of a certain mass of nerve cells operating at a reduced level from the general cortical activity leads to a weakening of the performance of the cortex, to a decrease in individual abilities, and to peculiar forms of cerebral asthenia.

Applying this position to our cases, we can assume that some forms of undeveloped individual abilities in students who have suffered from a brain disease, for example, reading, writing, counting, as well as some types of speech deficiencies, weakening of memory, shifts in the emotional sphere are based on the presence stagnant inhibitory process, causing a violation of the mobility of general neurodynamics. Improvement in development, activation of weakened abilities, as witnessed by the school, occurs gradually, as the individual areas cortical mass from inhibition. However, it would be an attempt to simplify to explain the noticeable improvements that occur in the condition of children who have suffered trauma, encephalitis, only by the gradual removal of protective inhibition.

Based on the very nature of this type of healing process, which is a unique form of self-medication of the body, it should be assumed that the removal of protective inhibition from certain areas of the cerebral cortex is associated with the simultaneous development of a whole complex of restorative processes (resorption of foci of hemorrhage, normalization of blood circulation, reduction of hypertension and a number of others ).

It is known that sleep usually does not occur immediately. Between sleep and wakefulness there are transitional periods, the so-called phase states, which cause drowsiness, which is some kind of threshold to sleep. Normally, these phases can be very short-lived, but in pathological conditions they are fixed for a long time.

Laboratory studies have shown that animals (dogs) react differently to external stimuli during this period. In this regard, it was highlighted special forms phase states. The equalizing phase is characterized by the same reaction to both strong and weak stimuli; during the paradoxical phase, weak stimuli produce a noticeable effect, and strong ones – an insignificant one, and during the ultraparadoxical phase, positive stimuli have no effect at all, and negative ones cause a positive effect. Thus, a dog in an ultraparadoxical phase turns away from food offered to it, but when the food is removed, it reaches for it.

Patients with certain forms of schizophrenia sometimes do not answer the questions of others asked in a normal voice, but they give an answer to a question addressed to them, asked in a whisper. The occurrence of phase states is explained by the gradual spread of the inhibitory process throughout the cerebral cortex, as well as the strength and depth of its effect on the cortical mass.

Natural sleep in the physiological sense is a diffuse inhibition in the cerebral cortex, extending to some of the subcortical formations. However, inhibition may be incomplete, then sleep will be partial. This phenomenon can be observed during hypnosis. Hypnosis is a partial sleep in which certain areas of the cortex remain excited, which determines the special contact between the doctor and the person being hypnotized. Various types of sleep treatments and hypnosis have become part of the therapeutic arsenal, especially in the clinic of nervous and mental diseases.

Irradiation, concentration and mutual induction of nerves

processes

Excitation and inhibition (retention) have special properties that naturally arise during the implementation of these processes. Irradiation is the ability of excitation or inhibition to spread, spread across the cerebral cortex. Concentration is the opposite property, i.e. the ability of nervous processes to gather and concentrate at any one point. The nature of irradiation and concentration depends on the strength of the stimulus. I.P. Pavlov pointed out that with weak irritation, irradiation of both irritating and inhibitory processes occurs, with irritants of medium strength - concentration, and with strong ones - irradiation again.

By mutual induction of nervous processes we mean the closest connection of these processes with each other. They constantly interact, conditioning each other. Emphasizing this connection, Pavlov figuratively said that excitation will give rise to inhibition, and inhibition will give rise to excitation. There are positive and negative induction.

These properties of the basic nervous processes are distinguished by a certain constancy of action, which is why they are called the laws of higher nervous activity. What do these laws established in animals provide for understanding the physiological activity of the human brain? I.P. Pavlov pointed out that it can hardly be disputed that the most general basics higher nervous activity, confined to the cerebral hemispheres, is the same in both higher animals and humans, and therefore the elementary phenomena of this activity should be the same in both. Undoubtedly, the application of these laws, adjusted for that special specific superstructure that is characteristic only of humans, namely the second signaling system, will help in the future to better understand the basic physiological patterns that operate in the human cerebral cortex.

The cerebral cortex is integrally involved in certain nervous acts. However, the degree of intensity of this participation in certain parts of the cortex is not the same and depends on which analyzer the person’s active activity in this segment time. So, for example, if this activity for a given period is primarily associated with the visual analyzer in nature, then the leading focus (working field) will be localized in the region of the brain end of the visual analyzer. However, this does not mean that during this period only the visual center will work, and all other areas of the cortex will be turned off from activity. Everyday life observations prove that if a person is engaged in an activity primarily related to the visual process, such as reading, then he simultaneously hears sounds coming to him, the conversation of others, etc. However, this other activity - let's call it secondary - is carried out inactively, as if in the background. The areas of the cortex that are associated with side activities are, as it were, covered with a “haze of inhibition”; the formation of new conditioned reflexes there is limited for some time. When moving to an activity associated with another analyzer (for example, listening to a radio broadcast), the active field, the dominant focus, moves from the visual analyzer to the auditory one in the cerebral cortex, etc. More often, several active foci are simultaneously formed in the cortex, caused by external and internal stimuli of different nature. At the same time, these foci enter into interaction with each other, which may not be established immediately (“struggle of centers”). The active centers that have entered into interaction form a so-called “constellation of centers” or a functional-dynamic system, which for a certain period will be the dominant system (dominant, according to Ukhtomsky). When activity changes this system is inhibited, and in other areas of the cortex another system is activated, which takes the position of a dominant, in order to again give way to other functional-dynamic formations that have replaced them, again associated with new activity caused by the entry into the cortex of new irritations from the external and internal environment. This alternation of points of excitation and inhibition, caused by the mechanism of mutual induction, is accompanied by the formation of numerous chains of conditioned reflexes and represents the basic mechanisms of brain physiology. The dominant focus, the dominant, is the physiological mechanism of our consciousness. However, this point does not remain in one place, but moves along the cerebral cortex depending on the nature of human activity, mediated by the influence of external and internal stimuli.

Systematicity in the cerebral cortex

(dynamic stereotype)

The various irritations acting on the cortex are diverse in the nature of their influence: some have only an approximate value, others form neural connections, which are initially in a somewhat chaotic state, then are balanced by the inhibitory process, refined and form certain functional-dynamic systems. The stability of these systems depends on certain conditions of their formation. If the complex of acting irritations acquires some periodicity and the irritations arrive in a certain order over a certain time, then the developed system of conditioned reflexes is more stable. I.P. Pavlov called this system a dynamic stereotype.

Thus, a dynamic stereotype is a developed
a balanced system of conditioned reflexes that perform

specialized functions. The development of a stereotype is always associated with a certain nervous labor. However, after the formation of a certain dynamic system, the performance of functions is greatly facilitated.

The significance of the developed functional-dynamic system (stereotype) is well known in the practice of life. All our habits, skills, and sometimes certain forms of behavior are determined by the developed system of nervous connections. Any change or violation of a stereotype is always painful. Everyone knows from life how difficult it is sometimes to perceive a change in lifestyle, habitual forms of behavior (breaking a stereotype), especially for older people.

The use of systematic cortical functions is extremely important in the upbringing and education of children. Reasonable, but steady and systematic presentation of a number of specific requirements to the child determines the strong formation of a number of general cultural, sanitary-hygienic and labor skills.

The question of the strength of knowledge is sometimes a sore point for schools. The teacher’s knowledge of the conditions under which a more stable system of conditioned reflexes is formed also ensures the students’ strong knowledge.

Often one has to observe how an inexperienced teacher, without taking into account the capabilities that higher education has, nervous activity students, especially in special schools, are taught the lesson incorrectly. When forming any school skill, it gives too many new irritations, and chaotically, without the necessary sequence, without dosing the material and without making the necessary repetitions.

So, for example, while explaining to children the rules for dividing multi-digit numbers, such a teacher suddenly gets distracted at the moment of explanation and remembers that this or that student did not bring a certificate of illness. Such inappropriate words, by their nature, are a kind of extra-irritant: they interfere with the correct formation of specialized systems of connections, which then turn out to be unstable and are quickly erased by time.

Dynamic localization of functions in the cortex

hemispheres

In constructing his scientific concept of localization of functions in the cerebral cortex, I.P. Pavlov proceeded from the basic principles of reflex theory. He believed that neurodynamic physiological processes occurring in the cortex necessarily have a root cause in the external or internal environment of the body, i.e. they are always deterministic. All nervous processes are distributed among the structures and systems of the brain. The leading mechanism of nervous activity is analysis and synthesis, which provide the highest form of adaptation of the body to environmental conditions.

Without denying the different functional significance of individual areas of the cortex, I.P. Pavlov substantiated a broader interpretation of the concept of “center”. On this occasion, he wrote: “And now it is still possible to remain within the limits of previous ideas about the so-called centers in the central nervous system. To do this, it would only be necessary to add a physiological point of view to the exclusive, as before, anatomical point of view, allowing for unification through a special well-trodden connections and paths of different parts of the central nervous system to perform a certain reflex act.”

The essence of the new additions made by I.P. Pavlov’s teaching on the localization of functions was, first of all, that he considered the main centers not only as local areas of the cortex, on which the performance of various functions, including mental ones, depends. The formation of centers (analyzers, according to Pavlov) is much more complicated. The anatomical region of the cortex, characterized by a unique structure, represents only a special background, the basis on which certain physiological activities develop, caused by the influence of various irritations of the external world and the internal environment of the body. As a result of this influence, nervous connections (conditioned reflexes) arise, which, gradually balancing, form certain specialized systems - visual, auditory, olfactory, gustatory, etc. Thus, the formation of the main centers occurs according to the mechanism of conditioned reflexes formed as a result of the interaction of the organism with the external environment.

The importance of the external environment in the formation of receptors has long been noted by evolutionary scientists. Thus, it was known that some animals living underground, where they do not reach sun rays, underdevelopment of the visual organs was noted, for example in moles, shrews, etc. The mechanical concept of the center as a narrow-local area in the new physiology was replaced by the concept of an analyzer - a complex device that ensures cognitive activity. This device combines both anatomical and physiological components, and its formation is due to the indispensable participation of the external environment. As mentioned above, I.P. Pavlov identified a central part at the cortical end of each analyzer - the nucleus, where the accumulation of receptor elements of this analyzer is especially dense and which corresponds to a certain area of ​​the cortex.

The core of each analyzer is surrounded by an analyzer periphery, the boundaries of which with neighboring analyzers are unclear and may overlap each other. Analyzers are closely interconnected by numerous connections that determine the closure of conditioned reflexes due to alternating phases of excitation and inhibition. Thus, the entire complex cycle of neurodynamics, proceeding according to certain patterns, represents a tuphysiological “canvas” on which a “pattern” of mental functions arises. In this regard, Pavlov denied the presence in the cortex of so-called mental centers (attention, memory, character, will, etc.), as if connected with certain local areas in the cerebral cortex. The basis of these mental functions are different states of the basic nervous processes, which also determine the different nature of conditioned reflex activity. So, for example, attention is a manifestation of the concentration of the excitatory process, in connection with which the formation of the so-called active or working field occurs. However, this center is dynamic, it moves depending on the nature of human activity, hence visual, auditory attention, etc. Memory, which usually means the ability of our cortex to store past experience, is also determined not by the presence of an anatomical center (memory center), but represents a totality numerous nerve traces (trace reflexes) that arose in the cortex as a result of stimuli received from the external environment. Due to constantly changing phases of excitation and inhibition, these connections can be activated, and then the necessary images appear in consciousness, which are inhibited when unnecessary. The same should be said about the so-called “supreme” functions, which usually included the intellect. This complex function of the brain was previously exclusively correlated with the frontal lobe, which was considered to be the only carrier of mental functions (the center of the mind).

In the 17th century the frontal lobes were seen as a thought factory. In the 19th century the frontal brain was recognized as an organ abstract thinking, the center of spiritual concentration.

Intelligence, a complex integral function, arises as a result of the analytical and synthetic activity of the cortex as a whole and, of course, cannot depend on individual anatomical centers in the frontal lobe. However, clinical observations are known when damage to the frontal lobe causes sluggishness of mental processes, apathy, and motor initiative suffers (according to Lhermit). The tracts observed in clinical practice led to views on the frontal lobe as the main center for the localization of intellectual functions. However, analysis of these phenomena in the aspect of modern physiology leads to other conclusions. The essence of the pathological changes in the psyche observed in the clinic with damage to the frontal lobes is not due to the presence of special “mental centers” affected as a result of the disease. This is about something else. Psychic phenomena have a certain physiological basis. This is a conditioned reflex activity that occurs as a result of alternating phases of excitatory and inhibitory processes. In the frontal lobe there is a motor analyzer, which is presented in the form of a nucleus and scattered periphery. The importance of the motor analyzer is extremely important. It regulates motor movements. Disruption of the motor analyzer due to various reasons (deterioration of blood supply, skull injury, brain tumor, etc.) may be accompanied by the development of a kind of pathological inertia in the formation of motor reflexes, and in severe cases, their complete blocking, which leads to various movement disorders (paralysis, lack of motor coordination ). Disorders of conditioned reflex activity are based on insufficiency of general neurodynamics; in them, the mobility of nervous processes is disrupted, and stagnant inhibition occurs.” All this, in turn, is reflected in the nature of thinking, the physiological basis of which is conditioned reflexes. A kind of rigidity of thinking, lethargy, lack of initiative arises - in a word, the whole complex of mental changes that were observed in the clinic in patients with damage to the frontal lobe and which were previously interpreted as the result of a disease of individual local points that carry “supreme” functions. The same should be said about the essence of speech centers. The lower parts of the frontal region of the dominant hemisphere, which regulate the activity of the speech organs, are separated into the speech motor analyzer. However, this analyzer also cannot be mechanically considered as a narrow local center of motor speech. Here only the highest analysis and synthesis of all speech reflexes coming from all other analyzers is carried out.

It is known that I.P. Pavlov emphasized the unity of the somatic and mental in the whole organism. In the studies of academician K.M. Bykov, the connection between the cortex and internal organs was experimentally confirmed. Currently, the so-called interoreceptor analyzer is located in the cerebral cortex, which receives signals about the state of internal organs. This area of ​​the cortex is conditionally - reflexively connected with everything internal structure our body. Facts from everyday life confirm this connection. Who does not know such facts when mental experiences are accompanied by various sensations from the internal organs? So, with excitement or fear, a person usually turns pale, often experiences an unpleasant sensation from the heart (“the heart sinks”) or from the gastrointestinal tract, etc. Corticovisceral connections have bilateral information. Hence, the primarily impaired activity of internal organs, in turn, can have a depressing effect on the psyche, causing anxiety, lowering mood, and limiting ability to work. The establishment of corticovisceral connections is one of the important achievements of modern physiology and is of great importance for clinical medicine.

Centers and activities can be considered in the same aspect
which were usually associated with the management of individual skills and labor
skills, such as writing, reading, counting, etc. These centers in the past also
were interpreted as local areas of the cortex with which graphical
and lexical functions. However, this idea from the standpoint of modern
physiology also cannot be accepted. In humans, as mentioned above, from
birth, there are no special cortical centers for writing and reading formed by specialized elements. These acts are specialized systems of conditioned reflexes that are gradually formed during the learning process.

However, how can we understand the facts that at first glance may confirm the presence of local cortical centers for reading and writing in the cortex? We are talking about observations of writing and reading disorders with damage to certain areas of the parietal lobe cortex. For example, dysgraphia (writing disorder) more often occurs when field 40 is affected, and dyslexia (reading disorder) most often occurs when field 39 is affected (see Fig. 32). However, it is wrong to believe that these fields are the direct centers of the described functions. The modern interpretation of this issue is much more complicated. The writing center is not only a group of cellular elements on which the specified function depends. The skill of writing is based on a developed system of neural connections. The formation of this specialized system of conditioned reflexes, which represent the physiological basis of the writing skill, occurs in those areas of the cortex where the corresponding junction of pathways occurs that connect a number of analyzers involved in the formation of this function. For example, to perform the function of writing, the participation of at least three receptor components is necessary - visual, auditory, kinesthetic and motor. Obviously, at certain points in the cortex of the parietal lobe, the closest combination of associative fibers occurs, connecting a number of analyzers involved in the act of writing. It is here that the closure of neural connections occurs, forming a functional system - a dynamic stereotype, which is the physiological basis of this skill. The same applies to field 39, associated with the reading function. As is known, the destruction of this area is often accompanied by alexia.

Thus, the reading and writing centers are not anatomical centers in a narrow local sense, but dynamic (physiological), although they arise in certain cortical structures. Under pathological conditions, during inflammatory, traumatic and other processes, systems of conditioned connections can quickly disintegrate. We are talking about aphasic, lexical and graphic disorders that develop after brain disorders, as well as the breakdown of complex movements.

In cases of optimal excitability of a particular point, the latter becomes dominant for some time and other points that are in a state of less activity are attracted to it. Between them, paths are paved and a unique dynamic system of working centers (dominant) is formed, performing one or another reflex act, as mentioned above.

It is characteristic that the modern doctrine of the localization of functions in the cerebral cortex is based on anatomical and physiological correlations. Now the idea that the entire cerebral cortex is divided into many isolated anatomical centers that are associated with the performance of motor, sensory and even mental functions will seem naive. On the other hand, it is also undeniable that all these elements are combined at any given moment into a system where each of the elements interacts with all the others.

Thus, the principle of functional unification of centers into certain working systems, in contrast to narrow static localization, is a new characteristic addition to the old doctrine of localization, which is why it received the name dynamic localization of functions.

A number of attempts have been made to develop the provisions expressed by I.P. Pavlov, in connection with the question of dynamic localization of functions. The physiological nature of the reticular formation as a tonic apparatus for cortical processes was clarified. Finally, and most importantly, ways were identified to explain the connections that exist between higher mental processes (as a complex product of socio-historical development) and their physiological basis, which was reflected in the works of L.S. Vygotsky, A.N. Leontyeva, A.R. Luria et al. “If higher mental functions are complexly organized functional systems, social in their genesis, then any attempt to localize them in special narrowly limited areas of the cerebral cortex, or centers, is even more unjustified than” an attempt to look for narrowly limited “centers” “for biological functional systems... Therefore, we can assume that the material basis of higher mental processes is the entire brain as a whole, but as a highly differentiated system, the parts of which provide different aspects of the whole.”

Reflex– the body’s response is not an external or internal irritation, carried out and controlled by the central nervous system. The development of ideas about human behavior, which has always been a mystery, was achieved in the works of Russian scientists I. P. Pavlov and I. M. Sechenov.

Reflexes unconditioned and conditioned.

Unconditioned reflexes- These are innate reflexes that are inherited by offspring from their parents and persist throughout a person’s life. The arcs of unconditioned reflexes pass through the spinal cord or brain stem. The cerebral cortex is not involved in their formation. Unconditioned reflexes ensure the organism's adaptation only to those changes in the environment that have often been encountered by many generations of a given species.

TO unconditioned reflexes include:

Food (salivation, sucking, swallowing);
Defensive (coughing, sneezing, blinking, withdrawing your hand from a hot object);
Indicative (squinting eyes, turning the head);
Sexual (reflexes associated with reproduction and care of offspring).
The importance of unconditioned reflexes lies in the fact that thanks to them the integrity of the body is preserved, the internal environment is maintained constancy and reproduction occurs. Already in a newborn child the simplest unconditioned reflexes are observed.
The most important of these is the sucking reflex. The stimulus of the sucking reflex is the touching of an object to the child’s lips (mother’s breast, pacifier, toy, finger). The sucking reflex is an unconditioned food reflex. In addition, the newborn already has some protective unconditioned reflexes: blinking, which occurs if a foreign body approaches the eye or touches the cornea, constriction of the pupil when exposed to strong light on the eyes.

Particularly pronounced unconditioned reflexes in various animals. Not only individual reflexes can be innate, but also more complex forms of behavior, which are called instincts.

Conditioned reflexes– these are reflexes that are easily acquired by the body throughout life and are formed on the basis of an unconditioned reflex under the action of a conditioned stimulus (light, knock, time, etc.). I.P. Pavlov studied the formation of conditioned reflexes in dogs and developed a method for obtaining them. To develop a conditioned reflex, a stimulus is needed - a signal that triggers the conditioned reflex; repeated repetition of the action of the stimulus allows you to develop a conditioned reflex. During the formation of conditioned reflexes, a temporary connection arises between the centers of the analyzers and the centers of the unconditioned reflex. Now this unconditioned reflex is not carried out under the influence of completely new external signals. These stimuli from the outside world, to which we were indifferent, can now acquire vital significance. Throughout life, many conditioned reflexes are developed that form the basis of our life experience. But this vital experience has meaning only for a given individual and is not inherited by its descendants.

In a separate category conditioned reflexes distinguish motor conditioned reflexes developed during our lives, i.e. skills or automated actions. The meaning of these conditioned reflexes is to master new motor skills and develop new forms of movements. During his life, a person masters many special motor skills related to his profession. Skills are the basis of our behavior. Consciousness, thinking, and attention are freed from performing those operations that have become automated and become skills of everyday life. Most successful path Mastering skills means systematic exercises, correcting errors noticed in time, and knowing the ultimate goal of each exercise.

If you do not reinforce the conditioned stimulus with the unconditioned stimulus for some time, then inhibition of the conditioned stimulus occurs. But it doesn't disappear completely. When the experience is repeated, the reflex is restored very quickly. Inhibition is also observed when exposed to another stimulus of greater strength.

8. The individuality of conditioned reflexes is manifested in the fact that 1) an individual inherits only certain conditioned reflexes 2) each individual of the same species has its own life experience 3) they are formed on the basis of individual unconditioned reflexes 4) each individual has an individual mechanism for the formation of a conditioned reflex

• 20-09-2010 15:22
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Answers (1) Alinka Konkova +1 09/20/2010 20:02

I think 1))))))))))))))))))))))

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1. What reflexes are called conditioned? Give examples of a conditioned reflex.

Conditioned reflexes are acquired by the body in the process of its development, i.e. they are individual. Conditioned reflexes do not have ready-made reflex arcs; they are formed under certain conditions. These reflexes are not constant; they can develop and disappear. The conditioned reflex is formed on the basis of the unconditioned reflex and is carried out due to the activity of the cerebral cortex. For the formation of conditioned reflexes, it is necessary to combine two stimuli in time: an indifferent (conditioned) one for a given type of activity (light, sound, for example, for digestion) and an unconditioned one, causing a certain unconditioned reflex (food, etc.). The conditional signal must precede the unconditional signal. Reinforcement of the conditioned signal by the unconditioned must be repeated in the absence of distracting extraneous stimuli. When a conditioned stimulus (for example, light) acts, a focus of excitation appears in the cortex. The subsequent action of an unconditioned stimulus (for example, food) is accompanied by the appearance of a second focus of excitation in the cortex. A temporary connection arises between them (a Pavlovian closure occurs). After several combinations of conditioned and unconditioned stimuli, the connection becomes stronger. Now only one conditioned stimulus is enough to trigger a reflex. An example of a conditioned reflex: salivation at the sight and smell of food.

Conditioned reflexes are not only developed, but also disappear or weaken when the conditions of existence change as a result of inhibition. I.P. Pavlov distinguished two types of inhibition of conditioned reflexes: unconditioned (external) and conditioned (internal). Unconditioned (external) inhibition occurs as a result of the action of a new stimulus of sufficient strength. In this case, a new focus of excitation appears in the cerebral cortex, which causes inhibition of the existing focus of excitation. In a person, for example, with an acute toothache, a severely wounded finger stops hurting. Conditioned (internal) inhibition develops according to the laws of the conditioned reflex, i.e. if the action of the conditioned stimulus is not reinforced by the action of the unconditioned stimulus. Thanks to inhibition in the cortex, unnecessary temporary connections disappear.

2. What reflexes are called unconditioned? Give examples of an unconditioned reflex.Material from the site

Unconditioned reflexes are innate and inherited. Unconditioned reflexes appear at the first application of the stimulus to the corresponding receptors. These reflexes have permanent inherited ready reflex arcs. They are inherent in all representatives of this species and are carried out in response to adequate stimulation. Unconditioned reflexes occur at the level of the spinal cord and brain stem, subcortical nuclei. Examples: salivation, swallowing, breathing, etc.

Unconditioned reflexes- These are innate, hereditarily transmitted reactions of the body. Conditioned reflexes- these are reactions acquired by the body in the process of individual development based on “life experience”.

Unconditioned reflexes are specific, that is, characteristic of all representatives of a given species. Conditioned reflexes are individual: some representatives of the same species may have them, while others may not.

Unconditioned reflexes are relatively constant; conditioned reflexes are not constant and, depending on certain conditions, they can be developed, consolidated or disappear; This is their property and is reflected in their very name.

Unconditioned reflexes are carried out in response to adequate stimulation applied to one specific receptive field. Conditioned reflexes can be formed to a wide variety of stimuli applied to various receptive fields.

In animals with a developed cerebral cortex, conditioned reflexes are a function of the cerebral cortex. After removing the cerebral cortex, the developed conditioned reflexes disappear and only unconditioned ones remain. This indicates that in the implementation of unconditioned reflexes, in contrast to conditioned ones, the leading role belongs to the lower parts of the central nervous system - the subcortical nuclei, brain stem and spinal cord. It should be noted, however, that in humans and monkeys, who have high degree corticalization of functions, many complex unconditioned reflexes are carried out with the obligatory participation of the cerebral cortex. This is proven by the fact that its lesions in primates lead to pathological disorders of unconditioned reflexes and the disappearance of some of them.

It should also be emphasized that not all unconditioned reflexes appear immediately at the time of birth. Many unconditioned reflexes, for example, those associated with locomotion and sexual intercourse, arise in humans and animals a long time after birth, but they necessarily appear under the condition of normal development of the nervous system. Unconditioned reflexes are part of the fund of reflex reactions strengthened in the process of phylogenesis and hereditarily transmitted.

Conditioned reflexes are developed on the basis of unconditioned reflexes. For the formation of a conditioned reflex, it is necessary to combine in time some kind of change in the external environment or the internal state of the body, perceived by the cerebral cortex, with the implementation of one or another unconditioned reflex. Only under this condition does a change in the external environment or internal state of the body become a stimulus for a conditioned reflex - a conditioned stimulus, or signal. The irritation that causes an unconditioned reflex - unconditioned irritation - must, during the formation of a conditioned reflex, accompany the conditioned irritation and reinforce it.

In order for the clinking of knives and forks in the dining room or the knocking of a cup from which a dog is fed to cause salivation in the first case in a person, in the second case in a dog, it is necessary to re-coincidence of these sounds with food - reinforcement of stimuli that are initially indifferent to salivary secretion by feeding , i.e., unconditional irritation of the salivary glands. Likewise, the flashing of an electric light bulb in front of a dog’s eyes or the sound of a bell will only cause conditioned reflex flexion of the paw if they are repeatedly accompanied by electrical irritation of the skin of the leg, causing an unconditioned flexion reflex whenever it is used.

Similarly, a child’s crying and his hands pulling away from a burning candle will be observed only if the sight of the candle first coincided at least once with the feeling of a burn. In all the above examples, external agents that are initially relatively indifferent - the clinking of dishes, the sight of a burning candle, the flashing of an electric light bulb, the sound of a bell - become conditioned stimuli if they are reinforced by unconditioned stimuli. Only under this condition do the initially indifferent signals of the external world become stimuli for a certain type of activity.

For the formation of conditioned reflexes, it is necessary to create a temporary connection, a closure between the cortical cells that perceive conditioned stimulation and the cortical neurons that are part of the unconditioned reflex arc.

Abstract on the topic:

"Conditioned and unconditioned reflexes"

Donetsk 2010

Introduction.

1. Teachings of I.P. Pavlov. Conditioned and unconditioned reflexes.

2. Classification of unconditioned reflexes.

3. The mechanism of formation of conditioned reflexes.

4. Conditions for the formation of conditioned reflexes.

5. Classification of conditioned reflexes.

Conclusion.

List of used literature.

Introduction.

Adaptation of animals and humans to changing conditions of existence in external environment is ensured by the activity of the nervous system and is realized through reflex activity. In the process of evolution, hereditarily fixed reactions (unconditioned reflexes) arose that combine and coordinate the functions of various organs and carry out adaptation of the body. In humans and higher animals, in the process of individual life, qualitatively new reflex reactions arise, which I. P. Pavlov called conditioned reflexes, considering them the most perfect form of adaptation. A reflex is the body’s response to any stimulus, carried out with the participation of the central nervous system.

1. Teachings of I.P. Pavlov. Conditioned and unconditioned reflexes.

I.P. Pavlov, while studying the processes of digestion, drew attention to the fact that in a number of cases, when eating food, the dog observed salivation not for the food itself, but for various signals that were in one way or another associated with food. For example, saliva was secreted by the smell of food, the sound of dishes from which the dog was usually fed. Pavlov called this phenomenon “mental salivation” as opposed to “physiological.” The assumption that the dog “imagined” how a familiar person would feed it from a bowl in which food is usually placed was categorically rejected by Pavlov as unscientific.

Before Pavlov, physiology mainly used methods in which all the functions of various organs were studied in an animal under anesthesia. At the same time, the normal functioning of both organs and the central nervous system was disrupted, which could distort the research results. To study the work of the higher parts of the central nervous system, Pavlov used synthetic methods that made it possible to obtain information from a healthy animal without disrupting the functions of the body.

When studying the processes of digestion, Pavlov came to the conclusion that the basis of “mental” salivation, like physiological one, is reflex activity. In both cases, there is an external factor - a signal that triggers the salivary reaction. The difference lies only in the nature of this factor. With “physiological” salivation, the signal is the direct perception of food by the taste buds of the oral cavity, and with “mental” salivation, the stimulus will be indirect signals associated with food intake: the type of food, its smell, the type of dishes, etc. Based on this, Pavlov came to the conclusion that the “physiological” salivary reflex can be called unconditioned, and the “psychological” salivation can be called conditioned. Thus, according to Pavlov, the higher nervous activity of any animal organism is based on conditioned and unconditioned reflexes.

Unconditioned reflexes are very diverse; they are the basis of the instinctive activity of the body. Unconditioned reflexes are innate and do not require special training. By the time of birth, the main hereditary fund of such reflexes is laid in animals and humans. But some of them, in particular the sexual ones, are formed after birth, as the nervous, endocrine and other systems undergo corresponding morphological and functional maturation.

Unconditioned reflexes provide the first, rough adaptation of the body to changes in the external and internal environment. Thus, the newborn’s body adapts to the environment through unconditioned reflexes of breathing, sucking, swallowing, etc.

Unconditioned reflexes are characterized by stability, which is determined by the presence in the central nervous system of ready-made, stable nerve connections for reflex excitation. These reflexes are specific in nature. Representatives of the same animal species have approximately the same fund of unconditioned reflexes. Each of them manifests itself upon stimulation of a specific receptive field (reflexogenic zone). For example, the pharyngeal reflex occurs when the posterior wall of the pharynx is irritated, the salivation reflex - when the receptors of the oral cavity are irritated, the knee, Achilles, elbow reflexes - when the receptors of the tendons of certain muscles are irritated, the pupillary - when a sharp change in illumination acts on the retina, etc. With irritation These reactions are not evoked by other receptive fields.

Most unconditioned reflexes can occur without the participation of the cerebral cortex and subcortical nodes. At the same time, the Centers of unconditioned reflexes are under the control of the cerebral cortex and subcortical nodes, which have a subordination (from the Latin sub - submission, ordinatio - putting in order) influence.

During the growth and development of the organism, the system of unconditional reflex connections still turns out to be limited, inert, and unable to provide sufficiently mobile adaptation reactions corresponding to fluctuations in the external and internal environment. More perfect adaptation of the body to constantly changing conditions of existence occurs thanks to conditioned reflex, i.e., individually acquired reactions. Conditioned reflex mechanisms of the brain are related to all types of activity of the body (to somatic and vegetative functions, to behavior), providing adaptive reactions aimed at maintaining the integrity and stability of the “organism-environment” system. I. P. Pavlov called a conditioned reflex a temporary connection between a stimulus and a response activity that occurs in the body under certain conditions. Therefore, in the literature, instead of the term “conditioned reflex,” the term “temporary connection” is often used, which includes more complex manifestations of animal and human activity, representing entire systems of reflexes and behavioral acts.

Conditioned reflexes are not innate and are acquired during life as a result of constant communication of the body with the external environment. They are not as stable as unconditioned reflexes and disappear in the absence of reinforcement. With these reflexes, responses can be associated with stimulation of a wide variety of receptive fields (reflexogenic zones). Thus, a conditioned food secretory reflex can be developed and reproduced by stimulation of different sense organs (vision, hearing, smell, etc.).

2. Classification of unconditioned reflexes.

The behavior of animals and humans is a complex interweaving of interconnected unconditioned and conditioned reflexes, which are sometimes difficult to distinguish.

The first classification of unconditioned reflexes was proposed by Pavlov. He identified six basic unconditioned reflexes:

1. food

2. defensive

3. genitals

4. approximate

5. parental

6. children's.

Food reflexes are associated with changes in the secretory and motor functioning of the organs of the digestive system and occur when receptors in the oral cavity and walls of the digestive tract are irritated. Examples include reflex reactions such as salivation and bile secretion, sucking, and the swallowing reflex.

Defensive reflexes - contractions of various muscle groups - occur in response to tactile or pain stimulation of receptors in the skin and mucous membranes, as well as under the action of strong visual, olfactory, sound or taste stimuli. Examples include withdrawal of the hand in response to the touch of a hot object, constriction of the pupil in harsh lighting.

Genital reflexes are associated with changes in the functions of the genital organs, caused by direct irritation of the corresponding receptors or the entry of sex hormones into the blood. These are reflexes associated with sexual intercourse.

Approximate Pavlov called the reflex the “what is it?” reflex. Such reflexes occur with sudden changes in the external environment surrounding the animal, or with internal changes in its body. The reaction consists of various acts of behavior that allow the body to become familiar with such changes. These can be reflex movements of the ears, head in the direction of the sound, or rotation of the body. Thanks to this reflex, a quick and timely response to all changes in environment and in your body. The difference between this unconditioned reflex and others is that when the action of the stimulus is repeated, it loses its indicative meaning.

Parental reflexes are reflexes that underlie care for offspring.

Children's reflexes are characteristic from birth and appear on certain, usually early stages development. An example of a child's reflex is the innate sucking reflex.

3. The mechanism of formation of conditioned reflexes.

According to I.P. Pavlov, a temporary connection is formed between the cortical center of the unconditioned reflex and the cortical center of the analyzer, the receptors of which are acted upon by the conditioned stimulus, i.e. the connection is made in the cerebral cortex. The closure of the temporary connection is based on the process of dominant interaction between excited centers. Impulses caused by an indifferent (conditioned) signal from any part of the skin and other sensory organs (eye, ear) enter the cerebral cortex and ensure the formation of a focus of excitation in it. If, after an indifferent signal, food reinforcement (feeding) is given, then a more powerful second focus of excitation arises in the cerebral cortex, to which the previously arisen and irradiating excitation along the cortex is directed. Repeated combination in experiments of a conditioned signal and an unconditioned stimulus facilitates the passage of impulses from the cortical center of the indifferent signal to the cortical representation of the unconditioned reflex - synaptic facilitation (blazing the path) - dominant. The conditioned reflex first becomes a dominant, and then a conditioned reflex.

I. P. Pavlov called the formation of a temporary connection in the cerebral cortex the closure of a new conditioned reflex arc: now the supply of only a conditioned signal leads to the excitation of the cortical center of the unconditioned reflex and excites it, i.e. a reflex to a conditioned stimulus occurs - a conditioned reflex.

4. Conditions for the formation of conditioned reflexes.

Conditioned reflexes are well formed only under certain conditions, the most important of which are:

1) repeated combination of the action of a previously indifferent conditioned stimulus with the action of a reinforcing unconditioned or previously well-developed conditioned stimulus;

2) some precedence in time of the action of the indifferent agent to the action of the reinforcing stimulus;

3) vigorous state of the body;

4) absence of other types of active activity;

5) a sufficient degree of excitability of an unconditional or well-fixed conditioned reinforcing stimulus;

6) suprathreshold intensity of the conditioned stimulus.

The coincidence of the action of an indifferent stimulus with the action of a reinforcing stimulus (an unconditioned or previously well-established conditioned stimulus) must, as a rule, be repeated several times. When new conditioned reflexes are formed in the same environment, the process of formation of these reflexes accelerates. In humans, many conditioned reflexes, especially to verbal stimuli, can be formed after one combination.

The duration of time preceding the action of a new conditioned stimulus to the action of a reinforcer should not be significant. Thus, in dogs, reflexes are developed especially well when the duration of the precedence is 5-10 seconds. When combined in the reverse order, when the reinforcing stimulus begins to act earlier than the indifferent stimulus, the conditioned reflex is not developed.

The formation of conditioned reflex connections, which easily occurs in a vigorous state of the body, becomes difficult when it is inhibited. Thus, in animals that are in a drowsy state, conditioned reflexes are either not formed at all, or are formed slowly and with difficulty. The inhibited state makes it difficult for humans to form conditioned reflexes.

When centers not associated with the formation of these conditioned reflexes dominate in the central nervous system, the formation of these reflexes becomes difficult. So, if a dog experiences sudden excitement, for example, at the sight of a cat, then under these conditions the formation of a food salivary reflex to the sound of a bell or the light of a light bulb does not occur. In a person absorbed in some activity, the formation of conditioned reflexes to other types of activity at this time is also greatly hampered.

Conditioned reflexes are formed only if there is sufficient excitability of the centers of these reinforcing reflexes. For example, when developing conditioned food reflexes in dogs, experiments are carried out under conditions of high excitability of the food center (the animal is in a hungry state).

The emergence and consolidation of a conditioned reflex connection occurs at a certain level of excitation of the nerve centers. In this regard, the strength of the conditioned signal should be above the threshold, but not excessive. To weak stimuli, conditioned reflexes are not developed at all or are formed slowly and are unstable. Excessively strong stimuli cause the development of protective (extraordinary) inhibition in nerve cells, which also complicates or eliminates the possibility of the formation of conditioned reflexes.

5. Classification of conditioned reflexes.

Conditioned reflexes are divided according to several criteria.

1. By biological significance distinguish:

1) food;

2) sexual;

3) defensive;

4) motor;

5) indicative - reaction to a new stimulus.

The indicative reflex occurs in 2 phases:

1) stage of nonspecific anxiety - 1st reaction to a new stimulus: motor reactions, autonomic reactions change, the rhythm of the electroencephalogram changes. The duration of this stage depends on the strength and significance of the stimulus;

2) stage of exploratory behavior: motor activity, autonomic reactions, and electroencephalogram rhythm are restored. Excitation covers a large part of the cerebral cortex and the formation of the limbic system. Result - cognitive activity.

Differences between the orienting reflex and other conditioned reflexes:

1) innate reaction of the body;

2) it can fade away when the stimulus is repeated.

That is, the orienting reflex occupies an intermediate place between the unconditioned and conditioned reflex.

2. By type of receptors, from which development begins, conditioned reflexes are divided into:

1) exteroceptive - form the adaptive behavior of animals in obtaining food, avoiding harmful effects, procreation, etc. For a person, exteroceptive verbal stimuli that shape actions and thoughts are of utmost importance;

2) proprioceptive - they form the basis for teaching animals and humans motor skills: walking, production operations, etc.;

3) interoceptive – affect mood and performance.

3. By division of the nervous system and the nature of the efferent response distinguish:

1) somatic (motor);

2) vegetative (cardiovascular, secretory, excretory, etc.).

IN depending on production conditions natural conditional reflexes (the conditioned stimulus is not used) are formed in response to signals that are natural signs of the reinforcing stimulus. Since natural conditioned reflexes are difficult to measure quantitatively (smell, color, etc.), I. P. Pavlov later moved on to the study of artificial conditioned reflexes.

Artificial – conditioned reflexes to such signal stimuli that in nature are not related to the unconditional (reinforced) stimulus, i.e. any additional stimulus is applied.

The main laboratory conditioned reflexes are the following.

1. By complexity distinguish:

1) simple - produced in response to single stimuli (classical conditioned reflexes of I. P. Pavlov);

2) complex - generated by several signals acting simultaneously or sequentially;

3) chain - produced by a chain of stimuli, each of which causes its own conditioned reflex.

2. By the ratio of the time of action of conditioned and unconditioned stimuli distinguish:

1) cash – development is characterized by the coincidence of the actions of conditioned and unconditioned stimuli, the latter is turned on later;

2) trace – produced under conditions when the unconditioned stimulus is presented 2-3 minutes after the conditioned stimulus is turned off, i.e. The development of a conditioned reflex occurs in response to a signal stimulus.

3. By development of a conditioned reflex on the basis of another conditioned reflex distinguish between conditioned reflexes of the second, third and other orders.

1) first-order reflexes – conditioned reflexes developed on the basis of unconditioned reflexes;

2) second-order reflexes - developed on the basis of first-order conditioned reflexes, in which there is no unconditioned stimulus;

3) third-order reflex - developed on the basis of a conditioned second order.

The higher the order of conditioned reflexes, the more difficult it is to develop them.

IN depending on the signaling system distinguish conditioned reflexes to signals of the first and second signaling systems, i.e. In other words, the latter are produced only in humans.

According to the body's reactions, conditioned reflexes are positive and negative.

Conclusion.

The great merit of I.P. Pavlov is that he extended the doctrine of reflex to the entire nervous system, starting from the lowest departments and ending with its highest departments, and experimentally proved the reflex nature of all forms of vital activity of the body without exception.

Thanks to reflexes, the body is able to respond in a timely manner to various changes in the environment or internal state and adapt to them. With the help of reflexes, a constant, correct and accurate relationship between parts of the body and the relationship of the whole organism to environmental conditions is established.

List of used literature.

1. Physiology of higher nervous activity and sensory systems: A guide for passing the exam. / Stupina S. B., Filipiechev A. O. - M.: Higher Education, 2008.

2. Physiology of higher nervous activity with the basics of neurobiology: Textbook for students. Biol. Specialties of universities / Shulgovsky V.V. – M.: Publishing Center “Academy”, 2009.

3. Physiology of sensory systems and higher nervous activity: textbook. aid for students higher textbook institutions / Smirnov V.M., Budylina S.M. – 3rd ed., rev. and additional – M.: Publishing Center “Academy”, 2007.

4. Philosophical Dictionary/ Ed. I.T. Frolova. - 4th ed. - M.: Politizdat, 2007.