Hepatoprotective effect of the radiation countermeasure flagellin in the long term after irradiation of mice.

Purpose: Purpose is to study the hepatoprotective effect of a new promising radiation countermeasure flagellin, in the long term after irradiation. The results of the study can be useful for mitigating the consequences of man-made radiation accidents, protecting professional contingents, reducing the toxic effect of radiation therapy, and expanding the range of drug use.

Materials And Methods: Effect of flagellin was investigated 10 months after its administration of irradiated male of mice F1 (CBAхC57Bl/6).

[Recombinant thrombopoietin antiradiation therapeutic effectiveness evaluation on dogs according to hemopoiesis and survival criteria].

Recombinant human thrombopoietin (rh TPO) has been investigated as a means of acute radiation disease urgent treatment in the experiments on 24 mongrel dogs. The animals were exposed to total acute gamma-irradiation at the doses of 3.5 Gy (exceeding LD50/45 under our conditions) and 3 Gy.

[Influence of indoinetophene on the antiradiation properties of indralin].

Radioprotective properties of indralin were studied at its combined administration with indometophene in the periods optimal for each preparation before acute radiation exposure. Animals were subjected to total radiation on the IGUR installation (137Cs): mice of the strain (CBA x C57B1) F1 at a dose of 9 Gy (LD100/30), purebred dogs--4 Gy (LD100/45). It was established in the experiments on mice that considerable radioprotective effect can be obtained by the use of indralin at a dose that is half the optimal radioprotective dose if it is applied against the background of indometophene administered at its optimal radioprotective dose four days before.

[Evaluation of the treatment effectiveness of domestic G-SCF preparations in experiments on irradiated dogs].

We have evaluated the treatment effectiveness of Leucostim and Neupomax in dogs exposed to radiation at lethal doses of 3 and 3.5 Gy, correspondingly, by testing the dynamics of the blood cell number, first of all, leucocytes and neutrophiles, and the 45-day survival. Supportive therapy for all the dogs, including the control ones, consisted in antibiotic treatment during the acute period of 7-24 days.

[The use of EPR spectroscopy to control the changes in organism radioresistance. Clinical results].

It has been shown that changes in Fe(3+)-transferrin and Cu(2+)-ceruloplasmin pools, which are trust-worthy controlled by the EPR technique in whole blood, blood plasma, and serum, as well as changes in the extracellular DNA content in blood plasma are markers of changes in organism radioresistance. This has been proved during the medical examination of the Chernobyl accident recovery workers and civil population, including children, exposed to low-intensity radiation, as well as during clinical investigation of new radioprotectors.

[The use of EPR spectroscopy to control the changes in organism radioresistance. Experimental results].

The responses of deoxyribonucleotide (dNTP), DNA, and protein synthesis systems in blood-forming organs of animals (dogs, mice) as well as changes in Fe(3+)-transferrin (Fe(3+)-TF) and Cu(2+)-ceruloplasmin (Cu(2+)-CP) pools in blood to gamma-irradiation and the administration of radioprotectors have been studied. It has been shown that changes in Fe(3+)-TF and Cu(2+)-CP pools in blood are indices of changes of body radioresistance and are reliably controlled by the EPR technique. An increase in the Fe(3+)-TF pool promotes the activation of synthesis of dNTP, DNA, and Fe(3+)-containing proteins, which are essential for repair efficiency during early post-irradiation time as well as for the development of compensatory and restorative reactions of cellular systems; i.

[Activation of deoxyribonucleotide synthesis by radioprotectants and antioxidants as a key stage in formation of body resistance to DNA-damaging factors].

The responses of the systems of synthesis of deoxyribonucleotides (dNTPs), DNA, and proteins in hematopoietic organs and liver of animals to gamma-radiation, administration of radioprotectants and antioxidants as well as the dependence of these responses on the doses of radiation and drugs were studied. Radioprotectants of acute (indralin) and durable effects (indomethaphen) as well as natural (alpha2-tocopherol) and synthetic anti-oxidants (ionol or 2,6-di-tert-butyl-4-methylphenol) efficient in survival test were used. Three stages could be recognized in the standard unspecific response of the studied systems to radiation: (1) immediate increase in ribonucleotide reductase activity in the tissues within the first 30 min as a part of the integrated SOS response to DNA damage, which activates dNTP synthesis; (2) inhibition of the synthesis of dNTPs, DNA, and and (3) restoring ribonucleotide reductase activity and integral increase in the production of dNTPs, DNA, and total protein, which is essential for the development of compensatory and restorative responses of the organism.

[Time- and dose-dependent post-irradiation changes of Fe3+-transferrin and Cu2+-ceruloplasmin pools in blood, their influence on ribonucleotide reductase activity in animal tissues and the effects of radioprotectors].

The time- and dose-dependent changes of Fe(3+)-transferrin (Fe(3+)-TF) and Cu(2+)-ceruloplasmin (Cu(2+)-CP) pools, of superoxide dismutase activity and the inhibitory activity of alpha 2-macroglobulin in blood as well as changes in synthesis rates of deoxyribonucleotides (dNTP), DNA and proteins in organs (spleen, liver, bone marrow, thymus) of mice and dogs given total body irradiation have been studied using of ESR spectroscopy, radioisotope techniques and biochemical determination of enzymatic activity. The experimental data have allowed us to reveal the sequence of organism's response reactions against irradiation and their modifications by radioprotectors. Changes in blood Fe(3+)-TF pool is one of the most informative, highly radiosensitive and rapidly reactive marker against irradiation and drug administrations.

[Influence of the indometafen radioprotector on the immune reactivity].

In the experiments on dogs and mice it was shown that indometophene could modify the immune status of the body. Specific and non-specific resistance of mice to E. coli infection increased after indometophene administration.

[Reactions of deoxyribonucleotide synthesis system to irradiation and their modification by radioprotectors].

The paper covers the problem on reactions of deoxyribonucleotide (dNTP) synthesis system in blood-forming organs of animals induced by irradiation. The synthesis of dNTP is a rate-limiting stage for DNA synthesis. Cellular requirements for dNTP pools during DNA synthesis are related with ensuring of the accuracy of DNA copying during replication and repair.

[Indometofen causes biochemical changes in the blood cells characteristic for a radioresistant state of the body].

The DNA and RNA contents, RNA/DNA ratio, and spontaneous and latex-induced oxidant activity indices of the whole blood were studied in the nitroblue tetrazolium test of mono- and polymorphonuclear blood leucocytes of intact dogs after injection of lipopolysaccharide pyrogenal. Significant changes in the above parameters were revealed for radioresistant (survived) and radiosensitive (lost) animals exposed to a subsequent prolonged gamma irradiation with a lethal dose of 7.64 Gy (LD75/45).

[The molecular mechanisms of the action of the radioprotector indometafen. The biosynthetic and bioenergetic aspects].

It was shown that indomethaphen (IM) is capable of stimulation of the synthesis of DNA, RNA, and protein precursors in mice. The IM-induced elevated level of the ribonucleotide reductase activity and, hence, deoxyribonucleotide pool in the spleen at the moment of irradiation and during the early postradiation period provides for complete DNA repair. As a result, the damaging effect of ionizing irradiation is weakened.

[The molecular aspects of the action of the radioprotector indralin].

The effect of indralin on the metabolic parameters in peripheral blood and organs of irradiated dogs and mice have been studied by EPR, NMR and radioisotope methods. It has been shown that indralin stimulated biosynthesis of DNA precursors as well as of DNA and proteins in the organs and stabilized the rate of ATP and glycogen synthesis. As a result indralin reduced considerably the changes produced by gamma-irradiation on the macromolecular biosynthesis during the early post-irradiation period.

[The dose dependence of the development of compensatory-restorative body reactions to irradiation. The EPR method].

The study deals with the mechanism of organism's adaptive responses to the effect of radiation in widely ranging dose. Post-irradiation metabolic changes were evaluated in canine blood as well as in murine blood, spleen, bone marrow and liver using the EPR spectroscopy. It was shown that the dynamics of changes in transferrin and ceruloplasmin pools and ribonucleotide reductase activity were phase-dependent with the maxima at the 2nd, 6th and 10-12th days after irradiation.