RU2727217C1 - Combined effect modeling method - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to simulation of gravity differing from gravitational force in combination with radiation action of cosmic rays on biological objects (BO) under conditions typical for Earth's orbit, surface of Mars, Moon and other celestial bodies. During clinostatting of BO in sealed capsule, clinostat is turned about horizontal axis to create centrifugal force equal to simulated force. Simultaneously, the preset time of the clinostat is withdrawn and held at altitude of 15–25 km by means of a stratostat. Capsule is equipped with a system for maintaining preset vital conditions for the analyzed BO. In this range of altitudes in the Earth's atmosphere there is a maximum radiation transfer of energy of cosmic rays, including a stream of secondary particles formed due to the nuclear cascade. Thus, realistic spectrum of primary cosmic rays and secondary particles is simulated.EFFECT: technical result consists in providing sufficiently reliable investigation of complex effect on BO of above space factors.1 cl

Description

The invention relates to the fields of knowledge in space medicine and simulation of space conditions characteristic of the Earth's orbit, the surface of Mars and the Moon and other celestial bodies, in particular to methods for modeling combined effects other than the earth's gravity, in combination with the radiobiological effects of cosmic rays.

The aim of the invention is to improve the reliability of modeling of space conditions by combining such space factors as gravity different from the earth and ionizing radiation of cosmic rays.

The invention is a method of creating conditions close to radiation and gravitational conditions in space by clinostating biological objects in a hermetically sealed capsule volume, brought out by an automatic stratospheric balloon to a height of 15-25 kilometers. The sealed volume of the capsule is equipped with a system for maintaining the specified laboratory conditions necessary for the vital activity of the biological objects under study (life support system), with the ability to use a clinostat inside this volume. The axis of rotation of the clinostat is directed perpendicular to the vector of the earth's gravity. The centrifugal force resulting from the rotation of the clinostat simulates the force of gravity to be simulated. The rotation parameters in the clinostat necessary for modeling the gravity F other than that of the Earth are determined by the formula:

where g is the acceleration imparted to the body of mass t by the centrifugal force F, R is the radius of rotation (the distance from the axis of rotation of the clinostat to the place of attachment of biological objects), w is the frequency of rotation.

The sealed capsule rises with an automatic stratospheric balloon and is located for a predetermined time in the altitude range of 15-25 kilometers. A characteristic feature of this altitude range is that the maximum radiation transfer of cosmic ray energy occurs in the Earth's atmosphere, including the flux of secondary particles formed due to the nuclear cascade, thereby simulating a realistic spectrum of primary cosmic rays and secondary particles.

The invention can be most effectively used to simulate the combined effects of gravity or weightlessness other than the earth's force and the action of cosmic rays on biological objects.

The known method of short-term (several tens of seconds) simulation of the combined effect of weightlessness and the action of cosmic rays on living organisms [1, 2].

The disadvantage of this method is its high cost and the need to use special aircraft or rockets. The time of action of the modeled factors is also strongly limited.

The closest in terms of the implementation principle and the equipment used is a method for simulating the combined action of weightlessness and space radiation by conducting experiments on board spacecraft [3-11].

The main difference of this method is its extreme high cost, and dependence on the launch time of the spacecraft, high risks associated with spacecraft launches, the need to comply with special requirements typical for the equipment used on board the spacecraft / rocket, the impossibility of creating gravitational conditions other than weightlessness.

In addition, the use of this method has certain limitations on the weight of the equipment, its functionality and the complexity of further research of biological material on Earth.

The technical result of the proposed invention is expressed:

- in the possibility of long-term observation of the joint effect different from the earth's gravity and cosmic radiation for a long time;

- in a significant reduction in the cost of experimental research;

- in the absence of significant restrictions on the use of experimental equipment;

- the ability to change the design of the experiment.

The essence of the invention consists in the development of a new effective method for simulating the conditions of stay of biological objects in celestial bodies and the Earth's orbit with a gravity different from that of the Earth, or in zero gravity, in combination with the effect of cosmic radiation.

The technical result is achieved by the fact that the biological objects under study are placed in a sealed capsule with a life support system, where the clinostat of these biological objects takes place, thereby simulating a given value of gravity and, using an automatic stratospheric balloon, the sealed capsule with biological objects is brought to an altitude of 15-25 km where biological objects are exposed to a realistic spectrum of cosmic rays, with the maximum intensity of radiation exposure from cosmic rays.

Method of implementing the invention:

1. Biological objects are placed in a clinostat (which is in a capsule) at the required radius, which is calculated by formula 1, in accordance with the specified value of the simulated gravity. And they set the necessary mode of rotation of the clinostat, which will correspond to the declared level of the simulated gravity.

2. Set the necessary conditions for the life support of biological objects (temperature, pressure, gas composition).

3. The capsule, with the help of an automatic stratospheric balloon, is launched to altitudes in the range of 15-25 km.

4. After a specified time, the capsule is lowered and selected for further research of biological objects.

List of literary sources

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2. Paul A.L. et al. Parabolic flight induces changes in gene expression patterns in Arabidopsis thaliana // Astrobiology. - 2011. - T. 11. - No. 8. - S. 743-758.

3. Andreev-Andrievsky A.A. et al. Experimental studies on mice under the flight program of the biosatellite "Bion-M1" // Aviation and Space and Environmental Medicine. - 2014. - T. 48. - No. 1. - S. 14-27.

4. Sychev V.N. et al. Project "Bion-M1": general characteristics and preliminary results // Aviation and space and environmental medicine. - 2014. - T. 48. - No. 1. - S. 7-14.

5. Wilson J.W. et al. Space flight alters bacterial gene expression and virulence and reveals a role for global regulator Hfq // Proceedings of the National Academy of Sciences. - 2007. - T. 104. - No. 41. - S. 16299-16304.

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7. Gridley D.S. et al. Spaceflight effects on T lymphocyte distribution, function and gene expression // Journal of applied physiology. - 2009. - T. 106. - No. 1. - C. 194-202.

8. Salmi M.L., Roux S.J. Gene expression changes induced by space flight in single-cells of the fern Ceratopteris richardii // Planta. - 2008. - T. 229. - No. 1. - C. 151-159.

9. Baqai F.P. et al. Effects of spaceflight on innate immune function and antioxidant gene expression // Journal of applied physiology. - 2009. - T. 106. - No. 6. - C. 1935-1942.

10. Hammond T.G. et al. Gene expression in space // Nature medicine. - 1999. - T. 5. - no. 4. - P. 359.

11. Wilson J.W. et al. Space flight alters bacterial gene expression and virulence and reveals a role for global regulator Hfq // Proceedings of the National Academy of Sciences. - 2007. - T. 104. - No. 41. - C. 16299-16304.

Claims (1)

A method for modeling the combined effect on biological objects other than the earth's gravity and ionizing radiation of cosmic rays, in which biological objects are placed in a sealed capsule and clinostatted in such a way that the centrifugal force arising from the rotation of the clinostat is equal to the simulated gravity, for example, the Moon or Mars, which differs the fact that the sealed capsule is lifted with an automatic stratospheric balloon and kept at an altitude of 15 to 25 km.