Справка
STUDENT'S CONSULTANT
Электронная библиотека технического вуза
Все издания
Login/Registration
Во весь экран / Свернуть
ru
Accessibility
General Catalogue
Все издания
Menu
Искать в книге
К результату поиска
Advanced search
Bookmarks
Homepage
Login/Registration
Во весь экран / Свернуть
ru
Управление
My reports
General Catalogue
Издательства
УГС
Мои списки
Download app
Pharmacology
Оборот титула
Table of contents
PREFACE
I. INTRODUCTION. 1. SUBJECT AND AIMS OF PHARMACOLOGY. ITS POSITION AMONG OTHER MEDICAL DISCIPLINES. MAIN STAGES OF PHARMACOLOGY DEVELOPMENT
2. CREATION OF NEW DRUGS
3. MAIN SECTIONS OF PHARMACOLOGY. PRINCIPLES OF CLASSIFICATION OF DRUGS
II. GENERAL PHARMACOLOGY
1. DRUG ADMINISTRATION ROUTES. ABSORPTION
2. DRUG DISTRIBUTION IN THE BODY. BIOLOGICAL BARRIERS. STORAGE
3. BIOTRANSFORMATION OF DRUGS IN THE BODY
4. ROUTES OF DRUG ELIMINATION FROM THE BODY
5. LOCAL AND SYSTEMIC EFFECTS OF THE DRUGS. DIRECT AND REFLEX EFFECTS. LOCALIZATION AND MECHANISM OF ACTION. DRUG «TARGETS». REVERSIBLE AND IRREVERSIBLE ACTIONS. SELECTIVE ACTION
6. DEPENDENCE OF PHARMACOTHERAPEUTIC ACTION ON DRUG PROPERTIES AND PATTERN OF USE
7. IMPORTANCE OF INDIVIDUAL CHARACTERISTICS OF THE HUMAN BODY AND ITS STATE FOR THE MANIFESTATION OF THE DRUG EFFECT
8. MAIN TYPES OF DRUG TREATMENT
9. PRINCIPAL AND ADVERSE EFFECT. ALLERGIC REACTIONS. IDIOSYNCRASY. TOXIC EFFECTS
10. GENERAL PRINCIPLES OF THE TREATMENT OF ACUTE DRUG POISONING 3
III. SPECIAL PHARMACOLOGY
A. Drugs affecting afferent innervation (Chapters 1, 2)
CHAPTER 1. DRUGS DECREASING SENSITIVITY OF AFFERENT NERVE ENDINGS OR PREVENTING THEIR EXCITATION
CHAPTER 2. DRUGS STIMULATING SENSORY NERVE ENDINGS
B. Drugs affecting efferent innervation
CHAPTER 3. DRUGS AFFECTING CHOLINERGIC SYNAPSES
CHAPTER 4. DRUGS AFFECTING ADRENERGIC SYNAPSES
C. Drugs regulating the functions of the central nervous system (Chapters 5-12)
CHAPTER 5. GENERAL ANESTHETICS
CHAPTER 6. ETHYL ALCOHOL
CHAPTER 7. HYPNOTICS
CHAPTER 8. PAIN-RELIEVING DRUGS (ANALGESICS)
CHAPTER 9. ANTIEPILEPTIC DRUGS
CHAPTER 10. ANTIPARKINSONIAN DRUGS
CHAPTER 11. PSYCHOTROPIC DRUGS
CHAPTER 12. ANALEPTICS
D. Drugs regulating functions of major organs and their systems
CHAPTER 13. DRUGS AFFECTING THE RESPIRATORY SYSTEM
Chapter 31
class="">
X-ray (roentgen) radiation
lass="">
X-ray (roentgen) radiation
ss="">
X-ray (roentgen) radiation
oentgen) radiationntgen) radiationgen) radiation">
X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
pan class="">
X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
n class="">
X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
class="">
X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
ass="">
X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
"">
X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
>
X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
i>X-radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.radiation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.diation is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.n is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.is electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic. electromagnetic waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.c waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.waves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.ves with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic. with a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.ith a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.h a wavelength of approximately from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.y from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.from 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.om 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic. 80 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.0 to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.to 10
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.
-5
nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.up>-5 nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.>-5 nm. X-radiation with the longest wavelength is overlapped by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic. by short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.y short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.short-wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.wave ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.ve ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic. ultraviolet radiation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.ation, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.ion, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.n, the short wavelength X-radiation is overlapped by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic. by long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.y long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.long wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.ng wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic. wavelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.avelength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.elength г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.gth г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.h г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.г-radiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.adiation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.iation. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.. According to the method of excitation, X-radiation is subdivided into continuous and characteristic.According to the method of excitation, X-radiation is subdivided into continuous and characteristic.cording to the method of excitation, X-radiation is subdivided into continuous and characteristic.method of excitation, X-radiation is subdivided into continuous and characteristic.thod of excitation, X-radiation is subdivided into continuous and characteristic.od of excitation, X-radiation is subdivided into continuous and characteristic.of excitation, X-radiation is subdivided into continuous and characteristic. excitation, X-radiation is subdivided into continuous and characteristic.xcitation, X-radiation is subdivided into continuous and characteristic.ivided into continuous and characteristic.ided into continuous and characteristic.ed into continuous and characteristic. into continuous and characteristic.nto continuous and characteristic.o continuous and characteristic.tinuous and characteristic.nuous and characteristic.ous and characteristic.
§ 31.1. X-RAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYS
pan class="">
§ 31.1. X-RAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYS
n class="">
§ 31.1. X-RAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYS
s="">
§ 31.1. X-RAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYS
"">
§ 31.1. X-RAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYS
>
§ 31.1. X-RAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYS
X-RAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYSRAY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYSY TUBE STRUCTURE. BREMSSTRAHLUNG X-RAYSSSTRAHLUNG X-RAYSTRAHLUNG X-RAYSAHLUNG X-RAYSLUNG X-RAYSNG X-RAYS X-RAYS-RAYSS/b>>pan>n>"txttspan class="">The most common source of X-ray is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.source of X-ray is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.urce of X-ray is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ce of X-ray is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. of X-ray is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.f X-ray is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.X-ray is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. is an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.s an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.an X-ray tube, which is a two-electrode vacuum device (fig. 31.1). Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.Heating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ating cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ing cathode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.thode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ode
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.e
1
emits electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.electrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ectrons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.trons 4. Anode 2, often called anti-cathode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.hode, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.de, has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil., has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.has an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.s an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.an inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. inclined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.lined surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ned surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.d surface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.rface in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ace in order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. order to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.rder to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.er to direct resulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.sulting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.lting X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ing X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. X-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.-ray radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ay radiation
3
at an angle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.gle to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.e to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.to the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. the horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.he horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. horizontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.zontal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ntal axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.al axis of the tube. The anode is made from a good conductive material to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ial to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.l to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.to remove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ove the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.e the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.the heat generated by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.d by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.by electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. electron impact. The anode surface is made from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ade from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.e from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.from refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.om refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. refractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.efractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ractory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ory materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.y materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.materials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.rials with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.als with a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.th a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. a large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. large atomic number in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.umber in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.ber in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.r in the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.n the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.the Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.e Mendeleev? periodic table, for example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.or example, tungsten. In certain cases, the anode is intentionally cooled with water or oil. example, tungsten. In certain cases, the anode is intentionally cooled with water or oil.xample, tungsten. In certain cases, the anode is intentionally cooled with water or oil.mple, tungsten. In certain cases, the anode is intentionally cooled with water or oil.le, tungsten. In certain cases, the anode is intentionally cooled with water or oil., tungsten. In certain cases, the anode is intentionally cooled with water or oil.gsten. In certain cases, the anode is intentionally cooled with water or oil.ten. In certain cases, the anode is intentionally cooled with water or oil.n. In certain cases, the anode is intentionally cooled with water or oil.r oil.oil.l.an>>
iv> lass="wrap-pagination">
ss="wrap-pagination">
="wrap-pagination">
wrap-pagination">
ap-pagination">
-pagination">
agination">
ation">
ion">
n">
class="pagination-book circle animated-effect">
ass="pagination-book circle animated-effect">
s="pagination-book circle animated-effect">
ook circle animated-effect">
k circle animated-effect">
circle animated-effect">
cle animated-effect">
e animated-effect">
animated-effect">
ss="arrow-to-start"> ="arrow-to-start"> arrow-to-start"> row-to-start"> w-to-start"> to-start"> art"> t"> > 785970459430-0000.html5970459430-0000.html70459430-0000.html30-0000.html-0000.html000.htmlg srctrns/book_read/to_start_book.pngns/book_read/to_start_book.png/book_read/to_start_book.pngook_read/to_start_book.pngk_read/to_start_book.pngread/to_start_book.pngad/to_start_book.pngo_start_book.pngstart_book.pngart_book.pngbook.pngok.pngервую страницурвую страницувую страницуую страницую страницу страницу"На первую страницуа первую страницу первую страницуервую страницурвую страницуую страницую страницу страницуeption-chapter"> tion-chapter"> on-chapter"> pter"> er"> "> efrary.ru/ru/doc/ISBN9785970459430-0008.htmlry.ru/ru/doc/ISBN9785970459430-0008.html.ru/ru/doc/ISBN9785970459430-0008.htmlu/ru/doc/ISBN9785970459430-0008.htmlru/doc/ISBN9785970459430-0008.html/doc/ISBN9785970459430-0008.htmloc/ISBN9785970459430-0008.htmlSBN9785970459430-0008.htmlN9785970459430-0008.html785970459430-0008.html70459430-0008.html459430-0008.html-0008.html008.html8.htmlg srcru/patrns/book_read/to_previous_chapter.png/patrns/book_read/to_previous_chapter.pngatrns/book_read/to_previous_chapter.pngrns/book_read/to_previous_chapter.pngs/book_read/to_previous_chapter.pngbook_read/to_previous_chapter.pngread/to_previous_chapter.pngad/to_previous_chapter.png/to_previous_chapter.pngавувууitleleдыдущую главуыдущую главудущую главу">
/div>
>
iv class="arrow-left-tab"> class="arrow-left-tab"> lass="arrow-left-tab"> t-tab"> tab"> b"> r.studentlibrary.ru/ru/doc/ISBN9785970459430-0008/052.htmlstudentlibrary.ru/ru/doc/ISBN9785970459430-0008/052.htmludentlibrary.ru/ru/doc/ISBN9785970459430-0008/052.htmlentlibrary.ru/ru/doc/ISBN9785970459430-0008/052.htmltlibrary.ru/ru/doc/ISBN9785970459430-0008/052.htmlibrary.ru/ru/doc/ISBN9785970459430-0008/052.htmly.ru/ru/doc/ISBN9785970459430-0008/052.htmlru/ru/doc/ISBN9785970459430-0008/052.html/ru/doc/ISBN9785970459430-0008/052.html/prior.studentlibrary.ru/patrns/book_read/to_previous_page.pngrior.studentlibrary.ru/patrns/book_read/to_previous_page.pngor.studentlibrary.ru/patrns/book_read/to_previous_page.pngdentlibrary.ru/patrns/book_read/to_previous_page.pngntlibrary.ru/patrns/book_read/to_previous_page.pnglibrary.ru/patrns/book_read/to_previous_page.png/book_read/to_previous_page.pngook_read/to_previous_page.pngk_read/to_previous_page.png="На предыдущую страницуа предыдущую страницу предыдущую страницуредыдущую страницуедыдущую страницуыдущую страницудущую страницуущую страницуую страницую страницутраницураницуаницу
-right-tab"> ight-tab"> ht-tab"> -tab"> ab"> "> <9430-0009/001.html30-0009/001.html-0009/001.html001.html1.htmlhtmlsrcc=/to_next_page.pngo_next_page.pngnext_page.pngxt_page.png_page.pngage.pnge.pngg" t=а следующую страницу следующую страницуледующую страницую страницу страницутраницураницуаницуницуледующую страницуедующую страницудующую страницуующую страницующую страницущую страницу страницустраницутраницуapter"> ter"> r">
/div>
ass="arrow-to-finish"> s="arrow-to-finish"> "arrow-to-finish"> rior.studentlibrary.ru/ru/doc/ISBN9785970459430-0010/001.htmlor.studentlibrary.ru/ru/doc/ISBN9785970459430-0010/001.html.studentlibrary.ru/ru/doc/ISBN9785970459430-0010/001.htmltudentlibrary.ru/ru/doc/ISBN9785970459430-0010/001.htmldentlibrary.ru/ru/doc/ISBN9785970459430-0010/001.htmlntlibrary.ru/ru/doc/ISBN9785970459430-0010/001.htmllibrary.ru/ru/doc/ISBN9785970459430-0010/001.htmlary.ru/ru/doc/ISBN9785970459430-0010/001.htmly.ru/ru/doc/ISBN9785970459430-0010/001.htmlru/ru/doc/ISBN9785970459430-0010/001.htmlu/doc/ISBN9785970459430-0010/001.htmldoc/ISBN9785970459430-0010/001.htmlBN9785970459430-0010/001.html9785970459430-0010/001.html85970459430-0010/001.html0/001.html001.html1.htmltmll"ior.studentlibrary.ru/patrns/book_read/to_finish_book.pngr.studentlibrary.ru/patrns/book_read/to_finish_book.pngstudentlibrary.ru/patrns/book_read/to_finish_book.pngudentlibrary.ru/patrns/book_read/to_finish_book.pngentlibrary.ru/patrns/book_read/to_finish_book.pngtlibrary.ru/patrns/book_read/to_finish_book.pngary.ru/patrns/book_read/to_finish_book.pngy.ru/patrns/book_read/to_finish_book.pngru/patrns/book_read/to_finish_book.pngнюю страницуюю страницую страницутраницураницуаницуtlee=ницуицуцуу
div>>
div class="col-md-3 col-sm-3 col-xs-3 wrap-contents hidden-xs left-column"> v class="col-md-3 col-sm-3 col-xs-3 wrap-contents hidden-xs left-column"> class="col-md-3 col-sm-3 col-xs-3 wrap-contents hidden-xs left-column"> ass="col-md-3 col-sm-3 col-xs-3 wrap-contents hidden-xs left-column"> col-md-3 col-sm-3 col-xs-3 wrap-contents hidden-xs left-column"> l-md-3 col-sm-3 col-xs-3 wrap-contents hidden-xs left-column"> md-3 col-sm-3 col-xs-3 wrap-contents hidden-xs left-column"> ul id="menu_left_catalogue-5" class="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
id="menu_left_catalogue-5" class="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
enu_left_catalogue-5" class="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
u_left_catalogue-5" class="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
left_catalogue-5" class="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
class="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
lass="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
ss="wrap-main-link-calogue">
Каталог
Издательства
УГС
Мои списки
-link-catalogue">
Каталог
Издательства
УГС
Мои списки
ink-catalogue">
Каталог
Издательства
УГС
Мои списки
k-catalogue">
Каталог
Издательства
УГС
Мои списки
catalogue">
Каталог
Издательства
УГС
Мои списки
talogue">
Каталог
Издательства
УГС
Мои списки
logue">
Каталог
Издательства
УГС
Мои списки
gue">
Каталог
Издательства
УГС
Мои списки
>
Каталог
Издательства
УГС
Мои списки
Каталог
Издательства
УГС
Мои списки
Каталог
Издательства
УГС
Мои списки
href="https://prior.studentlibrary.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
ef="https://prior.studentlibrary.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
tps://prior.studentlibrary.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
s://prior.studentlibrary.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
//prior.studentlibrary.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
library.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
brary.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
ary.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
.ru/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
u/ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
ru/pages/catalogue.html">
Каталог
Издательства
УГС
Мои списки
>Каталог
Издательства
УГС
Мои списки
аталог
Издательства
УГС
Мои списки
талог
Издательства
УГС
Мои списки
алог
Издательства
УГС
Мои списки
лог
Издательства
УГС
Мои списки
ог
Издательства
УГС
Мои списки
Издательства
УГС
Мои списки
span>
Издательства
УГС
Мои списки
an>
Издательства
УГС
Мои списки
s://prior.studentlibrary.ru/ru/pages/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
//prior.studentlibrary.ru/ru/pages/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
prior.studentlibrary.ru/ru/pages/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
studentlibrary.ru/ru/pages/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
udentlibrary.ru/ru/pages/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
entlibrary.ru/ru/pages/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
pages/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
ges/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
s/librarian_catalogue-pub.html">Издательства
УГС
Мои списки
ельства
УГС
Мои списки
льства
УГС
Мои списки
ьства
УГС
Мои списки
ства
УГС
Мои списки
тва
УГС
Мои списки
ва
УГС
Мои списки
а
УГС
Мои списки
/a>
УГС
Мои списки
>
УГС
Мои списки
УГС
Мои списки
li>
УГС
Мои списки
>
УГС
Мои списки
i class="main-link-catalogue">
УГС
Мои списки
class="main-link-catalogue">
УГС
Мои списки
ass="main-link-catalogue">
УГС
Мои списки
catalogue">
УГС
Мои списки
talogue">
УГС
Мои списки
logue">
УГС
Мои списки
ue">
УГС
Мои списки
">
УГС
Мои списки
УГС
Мои списки
dentlibrary.ru/ru/pages/librarian_catalogue-ugs.html">УГС
Мои списки
ntlibrary.ru/ru/pages/librarian_catalogue-ugs.html">УГС
Мои списки
library.ru/ru/pages/librarian_catalogue-ugs.html">УГС
Мои списки
brary.ru/ru/pages/librarian_catalogue-ugs.html">УГС
Мои списки
ary.ru/ru/pages/librarian_catalogue-ugs.html">УГС
Мои списки
y.ru/ru/pages/librarian_catalogue-ugs.html">УГС
Мои списки
ru/pages/librarian_catalogue-ugs.html">УГС
Мои списки
/pages/librarian_catalogue-ugs.html">УГС
Мои списки
ages/librarian_catalogue-ugs.html">УГС
Мои списки
main-link-catalogue">
Мои списки
in-link-catalogue">
Мои списки
-link-catalogue">
Мои списки
catalogue">
Мои списки
talogue">
Мои списки
logue">
Мои списки
f="https://prior.studentlibrary.ru/ru/pages/my_lists.html">Мои списки "https://prior.studentlibrary.ru/ru/pages/my_lists.html">Мои списки ttps://prior.studentlibrary.ru/ru/pages/my_lists.html">Мои списки _lists.html">Мои списки ists.html">Мои списки ts.html">Мои списки .html">Мои списки tml">Мои списки l">Мои списки >Мои списки и списки списки списки иски ски a>
Скачать приложение
Скачать приложение
Скачать приложение
iv class="wrap-headings">
Скачать приложение
class="wrap-headings">
Скачать приложение
Скачать приложение
iv class="wrap-but-d">
Скачать приложение
class="wrap-but-d">
Скачать приложение
lass="wrap-but-d">
Скачать приложение
ss="wrap-but-d">
Скачать приложение
="wrap-but-d">
Скачать приложение
p-but-d">
Скачать приложение
but-d">
Скачать приложение
t-d">
Скачать приложение
ss="btn btn-download btn-animated in-title">Скачать приложение
="btn btn-download btn-animated in-title">Скачать приложение
btn btn-download btn-animated in-title">Скачать приложение
n-download btn-animated in-title">Скачать приложение
download btn-animated in-title">Скачать приложение
wnload btn-animated in-title">Скачать приложение
ed in-title">Скачать приложение
in-title">Скачать приложение
n-title">Скачать приложение
s="fa fa-download">
"fa fa-download">
a fa-download">
fa-download">
-download">
ownload">
nload">
d">
>
/i>
/a>
>
>
"return-to-book">eturn-to-book">urn-to-book">-to-book">o-book">book">prior.studentlibrary.ru/ru/book/ISBN9785970459430.htmlior.studentlibrary.ru/ru/book/ISBN9785970459430.htmlr.studentlibrary.ru/ru/book/ISBN9785970459430.htmlstudentlibrary.ru/ru/book/ISBN9785970459430.htmludentlibrary.ru/ru/book/ISBN9785970459430.htmlentlibrary.ru/ru/book/ISBN9785970459430.htmlbrary.ru/ru/book/ISBN9785970459430.htmlary.ru/ru/book/ISBN9785970459430.htmly.ru/ru/book/ISBN9785970459430.htmlicss<>
Оглавление
div>
Оглавление
ass="title-contents">
Оглавление
s="title-contents">
Оглавление
"title-contents">
Оглавление
авление
вление
ление
ение
ние
ие
е
/span>
pan>
n>
h3>
>
iv class="table-of-contents">-of-contents">f-contents">contents">tents">nts">s">TCont-bkt1ont-bkt1t-bkt1bkt1t1