Creation of Awareness about Radio active Radition Damage on the public with medias Such as TV,Radio and Websites.
Giving Permission Granted in a Document by the Authority to a Legal Person Who full fill the Requirements and Standard.
Conducting Inspection based on: Regular inspection Programme and, Request from the customer,Verification Inspection, Inspection based on past profile of the institution.
Possible actions for non-compliance: Formal instructions assured and correct the infraction, Written warning for non – compliance, Suspension of or restrictions on, operation until regulatory infraction or safety condition is corrected.
Radioactive Waste Management and Processing
Make and maintain control with all relevant persons involved with radioactive waste to provide an authoritative point of advice and guidance, Establish and maintain a detail record keeping system for all stages of radioactive waste management, including the inventory of radioactive waste, Ensure that waste package for off- site transportation is prepared to be in compliance with Transport Regulations, Ensure that appropriate shielding, labeling, physical security and integrity of waste packages, Segregation, collection and characterization of radioactive waste, Treatment and conditioning of radioactive waste.
January 16, 2019, Ethiopian Radiation Protection Authority and the new emerging Salale University have signed MOU to enhance cooperation in different research programs and activities that are parallel with the major existence of the institutions.
Director General of ERPA Ato Solomon Getachew, President of Salae University Dr. Genanew Goffe, and other responsible bodies from both parties have discussed on the applicability of the MOU to achieve its objectives that are focused on the creation of awareness, practical training, regular communication and information exchange on the condition of radiation source, measurement taking, conducting cooperative research on radiation area and sharing data or measuring equipment for research purpose.
Dr, Genanew Goffe, president of the university said, as the university is new, it needs the cooperation of ERPA on laboratory instruments to give practical training for the students and researchers on the area f radiation.
ERPA is also interested to give practical training and laboratory assistance for researchers and students of the university who are in need to conduct a research on radiation source. And also the authority wants to conduct cooperative research and develop it with different symposium which can be organized by the university, said Ato Solomon, Director General at ERPA.
Finally both parties have discussed to actively benefit from the conducive environment of the university as it is surrounded by different industries which use radioactive materials for their production. Such environment will help researchers to get data for their research findings.
A linear accelerator (LINAC) customizes high energy x-rays or electrons to conform to a tumor’s shape and destroy cancer cells while sparing surrounding normal tissue. It features several built-in safety measures to ensure that it will not deliver a higher dose than prescribed and is routinely checked by a medical physicist to ensure it is working properly.
If you’re scheduled for radiation therapy using a LINAC, your radiation oncologist will collaborate with a radiation dosimetrist and a medical physicist to develop a treatment plan for you. Your doctor will double-check this plan before treatment begins and implement quality assurance procedures to ensure that each treatment is delivered in the exact same manner.
What is this equipment used for?
A linear accelerator (LINAC) is the device most commonly used for external beam radiation treatments for patients with cancer. The linear accelerator is used to treat all parts/organs of the body. It delivers high-energy x-rays or electrons to the region of the patient's tumor. These treatments can be designed in such a way that they destroy the cancer cells while sparing the surrounding normal tissue. The LINAC is used to treat all body sites, using conventional techniques, Intensity-Modulated Radiation Therapy (IMRT), Volumetric Modulated Arc Therapy (VMAT), Image Guided Radiation Therapy (IGRT), Stereotactic Radio surgery (SRS), and Stereotactic Body Radio Therapy (SBRT).
How does the equipment work?
The linear accelerator uses microwave technology (similar to that used for radar) to accelerate electrons in a part of the accelerator called the "wave guide," then allows these electrons to collide with a heavy metal target to produce high-energy x-rays. These high energy x-rays are shaped as they exit the machine to conform to the shape of the patient's tumor and the customized beam is directed to the patient's tumor. The beam is usually shaped by a multileaf collimator that is incorporated into the head of the machine. The patient lies on a moveable treatment couch and lasers are used to make sure the patient is in the proper position. The treatment couch can move in many directions including up, down, right, left, in and out. The beam comes out of a part of the accelerator called a gantry, which can be rotated around the patient. Radiation can be delivered to the tumor from any angle by rotating the gantry and moving the treatment couch.
Who operates this equipment?
The patient's radiation oncologist prescribes the appropriate treatment volume and dosage. The medical physicist and the dosimetrist determine how to deliver the prescribed dose and calculate the amount of time it will take the accelerator to deliver that dose. Radiation therapists operate the linear accelerator and give patients their daily radiation treatments.
How is safety ensured?
Patient safety is very important and is assured in several ways.
Before treatment is delivered to the patient, a treatment plan is developed and approved by the radiation oncologist in collaboration with the radiation dosimetrist and medical physicist. The plan is double-checked before treatment is given and quality-assurance procedures are performed to ensure that the treatment will be delivered as planned.
Quality assurance of the linear accelerator is very important. There are several systems built into the accelerator so that it will not deliver a higher dose than the radiation oncologist has prescribed. Each morning before any patients are treated, the radiation therapist performs checks on the machine to make sure that the radiation intensity is uniform across the beam and that it is working properly. In addition, the medical physicist conducts more detailed monthly and annual checks of the linear accelerator.
Modern linear accelerators also have internal checking systems that do not allow the machine to be turned on unless all the prescribed treatment requirements are met.
During treatment, the radiation therapist continuously observes the patient using a closed-circuit television monitor. There is also a microphone in the treatment room so that the patient can speak to the therapist if needed. Port films (x-rays taken with the treatment beam) or other imaging tools such as cone beam CT are checked regularly to make sure that the beam position doesn't vary from the original plan.
Safety of the staff operating the linear accelerator is also important. The linear accelerator sits in a room with lead and concrete walls so that the high-energy x-rays are shielded and no one outside of the room is exposed to the x-rays. The radiation therapist must turn on the accelerator from outside the treatment room. Because the accelerator only emits radiation when it is actually turned on, the risk of accidental exposure is extremely low.
- RadiologyInfo.org for patients (https://www.radiologyinfo.org/en/info.cfm?pg=linac)