Indicators of bacterial translocation intensity in experimental acute obstacles of thin and thick intestine

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Суванов, К., Нуралиев, Н., & Нуралиева, Х. (2020). Indicators of bacterial translocation intensity in experimental acute obstacles of thin and thick intestine. in Library, 20(1), 894–899. извлечено от https://inlibrary.uz/index.php/archive/article/view/13978
Кайим Суванов, Ташкентский государственный стоматологический институт

Научно-исследовательский институт санитарии, гигиены и профзаболеваний

Неккадам Нуралиев, Ташкентский государственный стоматологический институт

Научно-исследовательский институт санитарии, гигиены и профзаболеваний

Хафиза Нуралиева, Ташкентский государственный стоматологический институт

Научно-исследовательский институт санитарии, гигиены и профзаболеваний

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Аннотация

The aim was to study the germination of microorganisms in the mesenteric lymph nodes, liver, spleen, lungs, peripheral and portal blood, peritoneal exudate to assess the intensity of bacterial translocation (BT). It was established that in experimental acute obstruction of the small and large intestines, the intensity of BT or the percentage of germination of microorganisms from the extraintestinal organs of animals was most pronounced in mesenteric lymph nodes and the liver. The intensity of BT was directly proportional to the duration of the experiment.

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ACADEMICIA

A n I n t e r n a t i o n a l

M u l t i d i s c i p l i n a r y

R e s e a r c h J o u r n a l

( D o u b l e B l i n d R e f e r e e d & R e v i e w e d I n t e r n a t i o n a l J o u r n a l )

DOI NUMBER:

10.5958/2249-7137.2020.00147.0

INDICATORS OF BACTERIAL TRANSLOCATION INTENSITY IN

EXPERIMENTAL ACUTE OBSTACLES OF THIN AND THICK

INTESTINE

Suvonov Qayim Jahonovich*; Nuraliev Nekkadam Abdullaevich**;

Nuralieva Hafiza Otaevna***

1,3

Research Institute of Sanitation,

Hygiene and Occupational Diseases,

Ministry of Health of the Republic of Uzbekistan,

UZBEKISTAN

ABSTRACT

The aim was to study the germination of microorganisms in the mesenteric lymph nodes, liver,
spleen, lungs, peripheral and portal blood, peritoneal exudate to assess the intensity of bacterial
translocation (BT). It was established that in experimental acute obstruction of the small and
large intestines, the intensity of BT or the percentage of germination of microorganisms from the
extraintestinal organs of animals was most pronounced in mesenteric lymph nodes and the liver.
The intensity of BT was directly proportional to the duration of the experiment.

KEYWORDS: Bacterial Translocation, Microorganisms, Extra-Intestinal Organs,
Experimental Studies.

INTRODUCTION

Bacterial translocation (BT) is the passage of bacteria through the mucous membrane of the
gastrointestinal tract into the extraintestinal parts of the div [8].

The “BT phenomenon” is quite common [1, 5, 9]. Currently, this phenomenon is interpreted in
two ways: supporters of the first believe that BT develops under the influence of stress, injuries
or other external extreme influences and with a decrease in the activity of the div's immune
system, while it is a pathogenetic link in some diseases; supporters of the second believe that BT
is not only the transfer of pathogens of endogenous infections into the internal environment of
the div, but also is a natural protective mechanism of the div [4, 6, 10].


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It is known that most of the normal microflora are capable of translocation of Escherichia coli,
Proteus spr, some other representatives of the Enterobacteriaceae family, transient strains of
Bacillus subtillus, gram-positive aerobes, the ability to translate obligate anaerobes is low [1, 7,
11].

Justification of the relevance and relevance of these studies shows that numerous scientific
works are devoted to the clinical, pathogenetic, and diagnostic aspects of the problem, but
studies related to the microbiological aspects of BT formation and their place in the development
of endogenous infections have not been carried out sufficiently. In this regard, conducting
experimental microbiological studies to solve this problem are relevant.

Purpose of the study.

Studying and assessing the germination of microorganisms from

mesenteric lymph nodes (MLN), liver, spleen, lungs, peripheral and portal blood, peritoneal
exudate in the dynamics of the experiment to assess the intensity of BT in experimental acute
obstruction of the small and large intestines.

MATERIALS AND METHODS

When choosing an experimental material, the basis was the numerous studies on experimental
microbiology, the convenience of working with it, cheapness and the high possibility of
achieving the purity of the experiment in a methodological aspect. When working strictly
observed all the ethical principles of working with experimental animals and the rules of
biological safety.

For research, 240 white mongrel mice were used at the age of 2-3 months and weighing 18-25 g.

Before the experiments, all animals were divided into groups, then they were weighed for 3 days
and thermometry was performed. During these days, a decrease in div weight and an increase
in div temperature were not detected.

Identification and differentiation of seeded microorganisms was carried out by traditional
bacteriological methods. For this, nutrient media of HiMedia firm (India) were used.

The results are processed by traditional methods of variation statistics. All studies were
conducted on personal computers using the package of programs for biomedical research. The
organization and conduct of research is based on the principles of evidence-based medicine.

The results obtained and their discussion

In carrying out the studies, models of experimental acute obstruction of the small intestine
(EAOSI) and large intestine (EAOLI) proposed by Kruglyanskiy Yu.M. [3] in our modification.
Conducted 3 series of studies.

All laboratory animals are divided into 4 groups: 1 group - EAOSI, n = 72; Group 2 - EAOLI, n
= 72; Group 3 - animals in which the abdominal cavity was opened, but did not perform
obstruction (comparison group, n = 72); Group 4 - intact laboratory animals (control group, n =
24).

In turn, 1, 2, 3 groups were divided into subgroups: 1a, 2a and 3a - EAOSI and EAOLI lasting
24 hours (n = 8 each); 1b, 2b and 3b - EAOSI and EAOLI lasting 48 hours (n = 8 each); 1c, 2c
and 3c - EAOSI and EAOLI lasting 72 hours (n = 8 each).


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Considering the fact that during these periods the main clinical, pathological and morphological
changes in the intestinal walls associated with obstruction are observed [2, 3], we chose these
particular periods of the study.

Following aseptic rules, the abdominal cavity was opened with a sterile scalpel. For the
formation of EAOSI, a ligature was performed along the edges of the ileum bridle, while they
tried not to involve the breech into the pathological process. After the ligature, a purse string
suture was applied and pulled to create an obturation. After this, the abdominal cavity was
sutured with a surgical needle.

The same measures were taken to form EAOLI, but in contrast to EAOSI, obstruction was
performed on the distal part of the large intestine.

The laboratory animals of the third group (comparison group) opened the abdominal cavity and
sutured without applying a ligature to the small and large intestines.

In the control group (fourth group), surgery was not performed.

When opening the corpses of animals, precautionary measures were strictly observed to prevent
the introduction of microorganisms from the surface into the depth of the tissue, as well as their
transfer from one organ to another. Using sterilized instruments, the skin and subcutaneous tissue
were opened, biological material was taken first from the chest organs (lungs), then from the
abdominal organs (MLN, liver, spleen). However, with the help of a syringe, blood was taken
from the portal vein (portal blood) and the abdominal aorta (peripheral blood), as well as
peritoneal exudate from the abdominal cavity. To take the material from the organs of the
laboratory animal, they were first cauterized, then they were cut using sterile scissors and
grabbing a piece of the organ with tweezers they made an imprint on the surface of sterile pipette
media.

Given that normally all extraintestinal organs of laboratory animals are sterile, the growth of any
microorganism on the surface of culture media was evaluated as a bacterial translocation.

It was found that with EAOSI and EAOLI, the BT intensity was different depending on the
duration of the experiment and its type.

We have identified the following microorganisms that are representatives of the normal intestinal
microflora - Escherichia spp, Enterobacter spp, Citrobacter spp, Klebsiella spp, Proteus spp,
Staphylococcus spp, Enterococcus spp, Bacteroides spp.

The sowing rate of these microorganisms is described by our proposed microbiological criterion
that determines the intensity of BT - the percentage germination of microorganisms (PGM).

Studies have found that after EAOSI after a 24-hour period, the PGM for MLN was 45.8 ± 5.9%
(n = 33). This indicator increased to 91.7 ± 3.3% after 48 hours (n = 66), and after 72 hours this
parameter was 100% (n = 72). The difference between the periods was significant (P <0.05).

The liver PGM index differed from the same MLN parameters, so if after 24 hours
microorganisms from the liver were sown in 29.2 ± 5.4% (n = 21) cases, then after 48 and 72
hours these parameters were increased - to 56, respectively. 9 ± 5.8% (n = 41) and 81.9 ± 4.5%
(n = 59). When comparing with the results of a 24-hour period, the degree of reliability,
respectively, was P <0.02 and P <0.001.


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PGM from the spleen of animals sharply differed from the indicators of the previous organs
described. If microorganisms were not identified 24 hours after the start of the experiment, then
after 48 and 72 hours these indicators were 29.2 ± 5.4% (n = 21) and 31.9 ± 5.5% (n = 23),
respectively .

A distinctive feature of the plating of microorganisms from the lung parenchyma was that the
PGM was several times significantly low compared to other described organs. After the
formation of EAOSI after 24 hours, the growth of microorganisms from lung tissue was not
observed, while PGM after 48 and 72 hours was 9.7 ± 3.5% (n = 7) and 15.3 ± 4.2% (n =
eleven). When studying the indicators of the comparison and control groups, positive
bacteriological indicators were not obtained.

At the next stage of the studies, the intensity of BT on the extraintestinal organs of animals was
studied at various times with EAOLI.

It was found that in subgroup 2a (EAOLI after 24 hours) the PGM in MNL was at the level of
EAOSI - 41.7 ± 5.8% (n = 30) versus 45.8 ± 5.9% (P> 0.05) . But, 48 hours revealed significant
differences between these parameters - 59.7 ± 5.8% (n = 43) versus 91.7 ± 3.3%, (n = 66) - P
<0.001. Results after 72 hours were identical for EAOSI and EAOLI.

The results of studies on the liver showed the following results: PGM after 24 hours 18.1 ± 4.5%
(n = 13), after 48 hours 51.3 ± 5.9% (n = 37) and after 72 hours 80.6 ± 4.7% (n = 58). After 24
hours in the liver with EAOLI, PGM is 1.6 times reliably low compared with EAOSI, but after
48 hours there were no significant differences between the indicators (P <0.05).

The obtained results on PGM from the spleen differed from the results on MNL and liver. So
after 24 hours, cultures from the spleen gave a negative bacteriological result, but after 48 hours,
the growth of microorganisms was noted, where the PGM was 19.4 ± 4.7% (n = 14), after 72
hours the PGM was increased by 1.9 times compared with the previous result, 37.5 ± 5.7% (n =
27) - P <0.001.

The trend of changes in the results of studies on lung tissue were similar to the data of PGM of
the spleen. If it was not possible to identify microorganisms after 24 hours (0%), then after 48
hours this indicator was 16.7 ± 4.4% (n = 12), and after 72 hours the PGM significantly
increased 2.2 times (P <0.001 ) compared with the previous indicator - 36.1 ± 5.7% (n = 26).

In the spleen, in all periods of the experiment, there were no statistically significant differences
between the indicators, but the lung PGM parameters after 72 hours significantly differed 2.4
times between these models. As in studies with EAOSI with EAOLI, no growth of
microorganisms was found in the comparison and control groups.

The next stage of the study was the study of PGM of portal, peripheral blood and peritoneal
exudate in the same animals.

The results show that with EAOSI after 24 hours in the portal blood, the PGM was 33.3 ± 5.6%
(n = 24), and with EAOLI this indicator was 15.3 ± 5.6% (n = 11), which significantly lower
than the previous indicator. But, after 48 hours, these parameters significantly increased in
relation to the previous indicators - 56.9 ± 5.8% (n = 41) and 37.5 ± 5.7% (n = 27), respectively,
P <0.001. In addition, significant differences also persisted (P <0.001). When studying the data
of the next experimental period (72 hours) with EAOSI and EAOLI PGM was found in all


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animals - 100%, respectively (n = 72). It was found that these indices were 3.0 and 6.5 times,
respectively, significantly higher than the indices of the 24-hour period of the experiment, and
also, respectively, 1.8 and 2.7 times reliably more than the indices of the 48-hour experiment (P
<0.001 )

With these models and the timing of the experiment, microbiological studies were performed
with the peripheral blood of animals. The results show that in both models after 24 hours it was
not possible to identify microorganisms. But with an increase in the duration of the experiment
(48 hours), the growth of microorganisms was noted. The PGM indicators in both models were
19.4 ± 4.7% (n = 14) and 25.0 ± 5.1% (n = 18), respectively. The results obtained through the
72-hour experiment were somewhat different from the previous period. With EAOSI, the result
was not statistically different from the previous period (23.6 ± 5.0%, n = 17), but with EAOLI
the percentage of positive bacteriological samples was 1.9 times significantly higher (P <0.001)
than with 48 hourly experiment - 47.2 ± 5.9% (n = 34).

The PVM parameters of peritoneal fluid differed sharply from the parameters of peripheral
blood, but were close to portal blood data. The research results depending on the duration of the
experiment (24, 48, 72 hours) were as follows: with EAOSI, respectively - 48.6 ± 5.9% (n = 35),
65.2 ± 5.6% (n = 47) and 94.4 ± 2.7% (n = 68); EAOLI, respectively - 34.7 ± 5.6% (n = 25), 58.3
± 5.8% (n = 42) and 97.2 ± 1.9% (n = 70).

It should be emphasized that in both models only with a 24-hour period there were significant
differences between the figures obtained (P <0.05), with other periods the indicators did not
significantly differ from each other (P> 0.05).

Negative bacteriological results were obtained in the comparison and control groups during
microbiological studies of portal and peripheral blood. But, in the comparison group,
microorganisms were seeded from the peritoneal fluid after 48 and 72 hours, the PGM was equal
to 2.8 ± 1.9% (n = 2) and 4.2 ± 2.4% (n = 3), respectively. The control group data were identical
with other biological samples.

CONCLUSIONS

1.

With EAOSI and EAOLI, the intensities of BT or PGM from the extraintestinal organs of

laboratory animals at different times of the experiment differed.

2.

The intensity of BT was most pronounced in MLN and liver than in the spleen and lungs. The

intensity of this phenomenon was directly proportional to the duration of the experiment.

3.

PGM from MLN and liver are recommended as an experimental microbiological criterion for

assessing the intensity of bacterial translocation in an experiment.

REFERENCES

1.

Almagambetov K.Kh., Bondarenko V.M. Simulation of translocation of intestinal microflora

in conventional animals. ZhMEI. Moscow, 1991; 8: 11-17.

2.

Gostishchev A.N., Afanasyev Yu.M. Kruglyansky D.N., Sotnikov V.K. Bacterial translocation

in conditions of acute bowel obstruction. Bulletin of RAMS. Moscow, 2006; 9-10: 34-38.

3.

Kruglyansky Yu.M. Bacterial translocation in obstructive bowel obstruction (experimental

study): Abstract. dis. Cand. honey. sciences. Moscow, 2007: 24 p.


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ISSN: 2249-7137 Vol. 10, Issue 4, April 2020 Impact Factor: SJIF 2020 = 7.13

ACADEMICIA: An International Multidisciplinary Research Journal

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4.

Nikitenko V.I., Tkachenko E.I., Stadnikov A.A. The translocation of bacteria from the

gastrointestinal tract is a natural defense mechanism. Experimental and clinical gastroenterology.
Moscow, 2004; 1: 48-52.

5.

Nuraliev N.A., Ergashev V.A., Bektimirov A.M.-T. Bacterial translocation: etiology,

detectability and mechanisms of occurrence: a review. Journal of Clinical and Theoretical
Medicine. Tashkent, 2012; 7: 45-49.

6.

Titov V.N., Dugin S.F. Translocation syndrome, bacterial lipopolysaccharides, impaired

biological reactions of inflammation and blood pressure (lecture). Clinical laboratory
diagnostics. Moscow, 2010; 4: 21-37.

7.

Ergashev V.A., Nuraliev N.A. The phenomenon of bacterial translocation and the place of

microorganisms in its formation. Infection, immunity and pharmacology. Tashkent, 2014; 3: T.2:
236-239.

8.

Berg R.D. Bacterial translocation from the intestines. Jikken Dobutsu. 1985; 34(1): 1-16.

9.

Filos K.S., Kirkilesis I., Spiliopoulou I., Scopa C.D., Nikolopoulou V., Kouraklis G.,

Vagianos C.E. Bacterial translocation, endotoxaemia and apoptosis following Pringle manoeuvre
in rats. Injury. 2004; 35(1): 35-43.

10.

Gencay C., Kilicoglu S.S., Kismet K. et al. Effect of honey on bacterial translocation and

intestinal morphology in obstructive jaundice. World. J. Gastroenterology. 2008; Vol.14: 21:
3410-3415.

11

. Strobel O., Wachter D., Werner J., Uhl W., Müller C.A., Khalik M., Geiss H.K., Fiehn W.,

Büchler M.W., Gutt C.N. Effect of a pneumoperitoneum on systemic cytokine levels, bacterial
translocation, and organ complications in a rat model of severe acute pancreatitis with infected
necrosis. Surg Endosc. 2006; 20(12): 1897-903.

Библиографические ссылки

Almagambetov K.Kh., Bondarenko V.M. Simulation of translocation of intestinal microflora in conventional animals. ZhMEI. Moscow, 1991; 8: 11-17.

Gostishchev A.N., Afanasyev Yu.M. Kruglyansky D.N., Sotnikov V.K. Bacterial translocation in conditions of acute bowel obstruction. Bulletin of RAMS. Moscow, 2006; 9-10: 34-38.

Kruglyansky Yu.M. Bacterial translocation in obstructive bowel obstruction (experimental study): Abstract, dis. Cand. honey, sciences. Moscow, 2007: 24 p.

Nikitenko V.I., Tkachenko E.I., Stadnikov A.A. The translocation of bacteria from the gastrointestinal tract is a natural defense mechanism. Experimental and clinical gastroenterology. Moscow, 2004; 1: 48-52.

Nuraliev N.A., Ergashev V.A., Bektimirov A.M.-T. Bacterial translocation: etiology, detectability and mechanisms of occurrence: a review. Journal of Clinical and Theoretical Medicine. Tashkent, 2012; 7: 45-49.

Titov V.N., Dugin S.F. Translocation syndrome, bacterial lipopolysaccharides, impaired biological reactions of inflammation and blood pressure (lecture). Clinical laboratory diagnostics. Moscow, 2010; 4: 21-37.

Ergashev V.A., Nuraliev N.A. The phenomenon of bacterial translocation and the place of microorganisms in its formation. Infection, immunity and pharmacology. Tashkent, 2014; 3: T.2: 236-239.

Berg R.D. Bacterial translocation from the intestines. Jikken Dobutsu. 1985; 34(1): 1-16.

Filos K.S., Kirkilcsis L, Spiliopoulou I., Scopa C.D., Nikolopoulou V., Kouraklis G., Vagianos C.E. Bacterial translocation, endotoxaemia and apoptosis following Pringle manoeuvre in rats. Injury. 2004; 35(1): 35-43.

Gencay C., Kilicoglu S.S., Kismet K. et al. Effect of honey on bacterial translocation and intestinal morphology in obstructive jaundice. World. J. Gastroenterology. 2008; Vol.14: 21: 3410-3415.

Strobel O., Wachter D., Werner J., Uhl W., Muller C.A., Khalik M., Geiss H.K., Fiehn W., Biichler M.W., Gutt C.N. Effect of a pneumoperitoneum on systemic cytokine levels, bacterial translocation, and organ complications in a rat model of severe acute pancreatitis with infected necrosis. Surg Endosc. 2006; 20(12): 1897-903.

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