Question

Each of the following isotopes has been used medically for the purpose indicated. Suggest reasons why the particular element might have been chosen for this purpose a. cobalt-57, for study of the body's use of vitamin \(\mathrm{B}_{12}\) b. calcium- 47 , for study of bone metabolism c. iron-59, for study of red blood cell function

Short answer

Cobalt-57 is used for studying the body's use of vitamin B12 because of its similar chemical behavior to natural cobalt found in vitamin B12 and its detectable gamma radiation. Calcium-47 is used for studying bone metabolism as it can be incorporated into the bone like natural calcium, and its positron emissions can be externally detected to study calcium movement. Iron-59 is used for studying red blood cell function as it substitutes for natural iron in hemoglobin molecules, and its emitted beta particles can be externally detected for analysis. Each isotope has a suitable half-life for its respective study without causing significant radiation exposure to the patients.

Step-by-step solution

Understand Cobalt-57 properties

Cobalt-57 is a radioactive isotope with a half-life of 271.8 days. It decays by electron capture, leading to the production of gamma rays, which can be externally detected.

Suggest reasons for using Cobalt-57 in studying vitamin B12

Cobalt-57 has a similar chemical behavior to the natural cobalt in vitamin B12. This isotope can be incorporated into a compound that mimics vitamin B12 and introduced to the body. The gamma radiation emitted by Cobalt-57 can be detected from outside the body after the cobalt complex has been consumed. The slow decay, the half-life of 271.8 days, allows for enough time to study its absorption and utilization without causing significant harm to the patient. Therefore, Cobalt-57 is suitable for studying the body's use of vitamin B12.

Understand Calcium-47 properties

Calcium-47 is a radioactive isotope with a half-life of 4.54 days. It decays through beta decay, releasing positrons that can be externally detected.

Suggest reasons for using Calcium-47 in studying bone metabolism

Calcium is essential for bone health and its metabolism, and Calcium-47 can be incorporated into the bone, just like the natural calcium. The released positrons can be externally detected and used to study the bone metabolism. Due to the moderately short half-life of 4.54 days, Calcium-47 can provide real-time information on calcium movement in the body and reduce the risk of significant exposure to radiation. Therefore, Calcium-47 is suitable for studying bone metabolism.

Understand Iron-59 properties

Iron-59 is a radioactive isotope with a half-life of 44.6 days. It decays through beta decay, releasing beta particles that can be externally detected.

Suggest reasons for using Iron-59 in studying red blood cell function

Iron is an essential component of the hemoglobin molecule in red blood cells, which transport oxygen throughout our body. Iron-59 can substitute for natural iron in these molecules, and its emitted beta particles can be detected externally. The half-life of 44.6 days allows for a reasonable time to study the red blood cell function without causing significant radiation exposure to the patient. Consequently, Iron-59 is suitable for studying red blood cell function.

Key concepts

Cobalt-57

Cobalt-57 is an important radioactive isotope used in the medical study of how the human body utilizes vitamin B12. This isotope has a half-life of 271.8 days, which means it decays slowly over time.
This slow decay is beneficial as it allows researchers ample time to observe the absorption and utilization of vitamin B12 in the body without exposing patients to a lot of harmful radiation.
Cobalt-57 decays through a process called electron capture, resulting in the emission of gamma rays. These gamma rays can be detected from outside the body, making it possible to track how vitamin B12 is used in the body without invasive procedures.
Because Cobalt-57 behaves similarly to the natural cobalt found in vitamin B12, it can be effectively integrated into a compound that mimics the vitamin.

• The chemical similarity to natural cobalt makes it useful for tracking vitamin B12.
• Gamma rays emitted are detectable externally, aiding in non-invasive monitoring.
• The long half-life provides a sufficient timeframe for thorough study.

Calcium-47

Calcium-47 is a radioactive isotope that is highly beneficial in studying bone metabolism. With a half-life of just 4.54 days, it decays relatively quickly, but this short lifespan is strategic for certain medical studies.
This isotope undergoes beta decay, releasing positrons that can be detected from outside the body. Calcium is essential for forming and maintaining healthy bones, and calcium-47 can be absorbed and used by the bone in the same way as natural calcium.
The short half-life ensures that patients are exposed to minimal radiation, which makes it safer for them.

• It mimics natural calcium in bones, making it ideal for study.
• Positrons emitted can be detected externally for monitoring purposes.
• Its short half-life allows for quick evaluations, reducing radiation exposure.

Iron-59

Iron-59 is a critical isotope used for examining the functioning of red blood cells. It has a half-life of 44.6 days, which provides enough time to carefully study how red blood cells operate.
This isotope undergoes beta decay, releasing beta particles. These particles can be detected externally, which helps in understanding how the body uses iron, particularly in hemoglobin.
Iron is a vital component of hemoglobin, the molecule that allows red blood cells to carry oxygen throughout the body. By substituting Iron-59 for the natural iron in hemoglobin, researchers can trace the path and usage of iron in red blood cells without needing invasive methods.

• Suitable half-life allows extensive study with manageable radiation exposure.
• Beta particles provide insights into red blood cell function and iron utilization.
• Mimics natural iron, assisting in the exploration of red blood cell health.

Medical Imaging

Medical imaging is a process that allows healthcare providers to view the inside of a person's body using different imaging technologies. When it comes to using radioactive isotopes, the emitted radiation acts like a beacon that can be tracked using various imaging devices.
This form of imaging is crucial because it allows for non-invasive checking of internal processes and functions.

• Using gamma rays or other emitted particles, organs and tissues can be viewed externally.
• Radioactive isotopes such as Cobalt-57, Calcium-47, and Iron-59 are excellent markers.
• The method helps in diagnosing and understanding different physiological functions without surgery.

Radiation Detection

Radiation detection is essential in the field of medical diagnostics that utilize radioactive isotopes. Detection devices capture the emitted radiation from isotopes like gamma rays or beta particles to provide critical information about the state and functioning of the body.
This technology is the backbone of non-invasive medical investigations, making it possible to monitor physiological processes accurately.

• Allows safe and effective tracking of isotopes inside the body.
• Facilitates studies like those involving Cobalt-57, Calcium-47, and Iron-59.
• Ensures minimal exposure by selecting isotopes with appropriate half-lives and decay modes.