Dr Swagat Dash, HOD & Senior Consultant – Nuclear Medicine, Sarvodaya Hospital Faridabad explains the role of nuclear medicine
Nuclear medicine is a branch of medical science that employs radioactive substances to diagnose and treat diseases, marking a significant departure from traditional medical practices. Its ability to visualise, analyse, and treat conditions at a molecular level provides unparalleled insights and innovative solutions in healthcare.
Positron Emission Tomography (PET)
PET is a key nuclear medicine tool that uses radioactive tracers to detect metabolic changes at the cellular level, aiding early disease detection, particularly in oncology. PET scans provide detailed images of the body’s functional processes, contrasting with traditional imaging techniques that focus solely on anatomical structures.
Single Photon Emission Computed Tomography (SPECT)
Similarly, SPECT is another diagnostic tool that offers three-dimensional images of functional processes within the body. SPECT scans are widely used in cardiology to assess blood flow to the heart and detect coronary artery disease. In neurology, SPECT helps diagnose conditions like epilepsy and dementia by visualising brain activity.
Cancer detection and treatment
Early detection
Nuclear medicine significantly impacts oncology, enabling precise tumor localisation, staging, and treatment response monitoring through PET scans, thereby improving survival rates through early detection and intervention.
Targeted therapies
Nuclear medicine uses targeted therapies like I-131 and Lu-177 to destroy cancerous cells, improving overall survival and reducing side effects in thyroid and prostate cancer.
Cardiology:-
Myocardial Perfusion Imaging (MPI)
In cardiology, nuclear medicine plays a pivotal role in diagnosing and managing heart disease. MPI is a non-invasive technique that evaluates blood flow to the heart muscles, helping to detect coronary artery disease. By identifying areas with reduced blood flow, MPI guides treatment decisions, such as the need for angioplasty or bypass surgery.
Viability studies
Additionally, nuclear medicine techniques are used to assess myocardial viability, determining whether damaged heart tissue can benefit from revascularisation procedures. This information is crucial in deciding whether a patient should undergo invasive treatments, thereby optimising patient care and resource allocation.
Neurology :-
Brain imaging
Nuclear medicine has significantly advanced the field of neurology. PET and SPECT scans provide detailed images of brain activity, aiding in the diagnosis and management of neurological disorders. In Alzheimer’s disease, PET scans can detect amyloid plaques, which are characteristic of the disease, enabling early diagnosis and intervention.
Epilepsy and Parkinson’s Disease
SPECT and PET scans aid in identifying seizures and Parkinson’s disease, providing targeted treatment plans and improved patient outcomes through the visualization of dopamine-producing neuron loss.
Infection and inflammation imaging :-
Detecting infections
Nuclear medicine uses radiolabeled markers to detect infections and inflammation, aiding in accurate diagnosis and effective treatment planning in patients with complex conditions like orthopedic prosthesis and diabetic foot infections.
Inflammatory diseases
In rheumatology, nuclear medicine helps visualise inflammatory activity in diseases such as rheumatoid arthritis, enabling better disease management. By providing detailed images of inflammation, these techniques help monitor treatment response and adjust therapies accordingly.
Precision medicine:-
Personalised treatment
Nuclear medicine and molecular imaging are key in precision medicine, enabling personalised treatment plans, improved outcomes, and reduced healthcare costs by identifying disease targets and pathways.
Theranostics
A notable innovation in precision medicine is theranostics, which combines diagnostic imaging and targeted therapy. For example, using a single radiopharmaceutical for both detecting and treating prostate cancer exemplifies how theranostics enhances treatment precision and efficacy. This integrated approach is transforming how diseases are diagnosed and managed, paving the way for more personalised and effective treatments.
Emerging innovations:-
New radiopharmaceuticals
Nuclear medicine’s future is promising with advancements in radiopharmaceuticals and imaging techniques, improving diagnostic accuracy and expanding treatable conditions, such as cancer markers and inflammatory proteins.
Hybrid imaging
Hybrid imaging technologies like PET/MRI combine functional and anatomical imaging for comprehensive diagnostic information, enhancing nuclear medicine’s capabilities and making it a valuable healthcare tool.
Nuclear medicine enhances healthcare by providing advanced tools for disease diagnosis, treatment, and management, enabling early detection and precise treatment, driving medical innovation and personalised care.