Dose reconstruction during radiation therapy

The invention claimed is: 1. A method for the reconstruction of a dose administered to an object to be irradiated, the method comprising: recording a computed tomography image of the object to be irradiated with a single or multi slice computed tomography scanner, the single or multi slice computed tomography scanner comprising a kV x-ray source and an opposite kV detector for producing a computed tomography of the object positioned in a radiation therapy device; recording measurement data of a therapeutic treatment beam with a radiation therapy device, the radiation therapy device comprising a therapeutic radiation source for emitting the therapeutic treatment beam and a portal detector opposing the therapeutic radiation source for recording measurement data of the treatment beam once the treatment beam has left the object to be irradiated, the measurement data including portal images recorded during treatment; and reconstructing the dose administered to the object from the portal images recorded during treatment and the computed tomography image, wherein the reconstructing comprises: converting the portal images to energy fluences; and backprojecting the energy fluences using the computed tomography image as a model. 2. The method as claimed in claim 1 , further comprising: converting the measurement data of the portal detector into dose in water/dose to water values during the reconstruction of the dose administered to the object; and reconstructing the dose administered to the object from the dose in water/dose to water values using the computed tomography image. 3. The method as claimed in claim 1 , further comprising: rotating the portal detector about a center of rotation; and assigning the measurement data recorded by the portal detector to rotation positions, at which the recording of the measurement data has taken place, wherein reconstructing the dose administered to the object comprises reconstructing the dose administered to the object using the rotation positions assigned to the measurement data. 4. The method as claimed in claim 1 , wherein the computed tomography image is the only three dimensional (3D) image of the object that is used during the reconstruction of the dose administered to the object. 5. The method as claimed in claim 1 , wherein recording the computed tomography image comprises recording computed tomography images for a number of irradiation sessions, wherein reconstructing the dose administered to the object comprises reconstructing the dose administered for each of the irradiation sessions using the computed tomography image recorded in the irradiation session, and wherein the method further comprises determining an applied dose cumulated during the course of the irradiation sessions for a structure in the object. 6. The method as claimed in claim 2 , further comprising: rotating the portal detector about a center of rotation; and assigning the measurement data recorded by the portal detector to rotation positions, at which the recording of the measurement data has taken place, wherein reconstructing the dose administered to the object comprises reconstructing the dose administered to the object using the rotation positions assigned to the measurement data. 7. The method as claimed in claim 2 , wherein the computed tomography image is the only three dimensional (3D) image of the object that is used during the reconstruction of the dose administered to the object. 8. The method as claimed in claim 3 , wherein the computed tomography image is the only three dimensional (3D) image of the object that is used during the reconstruction of the dose administered to the object. 9. The method as claimed in claim 2 , wherein recording the computed tomography image comprises recording computed tomography images for a number of irradiation sessions, wherein reconstructing the dose administered to the object comprises reconstructing the dose administered for each of the irradiation sessions using the computed tomography image recorded in the irradiation session, and wherein the method further comprises determining an applied dose cumulated during the course of the irradiation sessions for a structure in the object. 10. The method as claimed in claim 3 , wherein recording the computed tomography image comprises recording computed tomography images for a number of irradiation sessions, wherein reconstructing the dose administered to the object comprises reconstructing the dose administered for each of the irradiation sessions using the computed tomography image recorded in the irradiation session, and wherein the method further comprises determining an applied dose cumulated during the course of the irradiation sessions for a structure in the object. 11. The method as claimed in claim 4 , wherein recording the computed tomography image comprises recording computed tomography images for a number of irradiation sessions, wherein reconstructing the dose administered to the object comprises reconstructing the dose administered for each of the irradiation sessions using the computed tomography image recorded in the irradiation session, and wherein the method further comprises determining an applied dose cumulated during the course of the irradiation sessions for a structure in the object. 12. A radiation therapy device for treatment of an object to be treated and for reconstruction of a dose administered to the object to be irradiated during the treatment, the radiation therapy device comprising: a therapeutic radiation source operable to emit a therapeutic treatment beam; a portal detector opposing the therapeutic radiation source, the portal detector operable to record measurement data of the therapeutic treatment beam once the therapeutic treatment beam has left the object to be irradiated, the measurement data including portal images recorded during treatment; a single or multi slice computed tomography scanner comprising a kV x-ray source and an opposing kV detector operable for producing a computed tomography of the object positioned in the radiation therapy device; and a control apparatus configured to: record a computed tomography image of the object to be irradiated with the single or multi slice computed tomography scanner during a treatment session; and reconstruct the dose administered to the object from the portal images recorded during treatment and the recorded computed tomography image, wherein the reconstruction comprises: conversion of the portal images to energy fluences; and backprojection of the energy fluences using the computed tomography image as a model. 13. The radiation therapy device as claimed in claim 12 , wherein the control apparatus is further configured to: convert the measurement data of the portal detector into dose in water/dose to water values; and reconstruct the dose administered to the object from the dose in water/dose to water values using the computed tomography image. 14. The radiation therapy device as claimed in claim 12 , wherein the portal detector is rotatable about a center of rotation; and wherein the control apparatus is further configured to: assign a rotation position, at which the measurement data has been recorded in each instance, to the measurement data recorded by the portal detector; and reconstruct the dose administered to the object using the rotation position assigned to the measurement data in each instance. 15. The radiation therapy device as claimed in claim 12 , wherein the control apparatus is further configured such that during the reconstruction of the dose administered to the objec