Radiotherapy

1. Therapeutic use of radiation in the management of cancer
   • Electromagnetic: photons, x-rays, gamma rays
   • Particulate: electrons, neutrons
2. Ionizing radiation = amount of energy absorbed per unit mass of tissue (measured in grays)
3. Delivery: linear accelerator
4. Mechanism of cellular damage
   • Damage of DNA - free radical formation leads to chromosomal damage and cellular death
   • Can also induce cellular apoptosis
   • Amount of damage is proportional to the dose of radiation

Planning treatment

Factors to consider

1. Radiosensitivity of tumour?
   • Highly sensitive: lymphoma, myeloma, seminoma
   • Moderately sensitive: breast, ovarian, teratoma, BCC, Small cell lung carcinoma
   • Moderately resistant: cervical carcinoma, bladder carcinoma, rectal carcionma, sarcomas
   • Highly resistant: melanoma, osteosarcoma, carcinoma of pancreas
2. Extent of tumour
3. Tolerance of normal tissues to radiation
   • Damage minimized by 3d imaging to ensure maximum radiation dose is delivered to tumour itself
   • Moulds created (as in head/neck cancers), tattoos of chest wall in breast cancer (ensure same position each time)
   • "Wedge" fields - multiple fields necessary
   • + "Shrinking" method to allow margins of treatment to be reduced during last few weeks of treatment

Complications

1. Acute
   • Fatigue
   • Anorexia, nausea
   • Skin irradatioatn- erythema/desquamation
   • Mucosal irradiation - diarrhoea
   • Dysphagia
   • Temporary alopecia
   • Sterility
2. Late
   • Telangectasia
   • Loss of saliva production
   • Pulmonary damage
   • Bowel strictures