伽马射线灭菌

Gamma irradiation sterilization is a form of ionizing radiation processing. The process utilizes gamma rays, which are a type of electromagnetic radiation with very short wavelengths and high energy, similar to X-rays but typically more energetic. The most common source for industrial sterilization is the radioisotope Cobalt-60 (⁶⁰Co). This isotope is produced in nuclear reactors and decays, emitting high-energy gamma photons. Products to be sterilized are placed on a conveyor system and passed through a heavily shielded concrete chamber (an irradiator) where they are exposed to the gamma radiation field for a specific duration. The key principle of its sterilizing action is the transfer of energy to the molecules within the microorganisms. When gamma photons pass through matter, they cause ionization by stripping electrons from atoms, creating highly reactive species such as free radicals (e.g., hydroxyl radicals from water). These free radicals indiscriminately attack and damage critical cellular components, with the most significant target being the microbial DNA. The radiation can cause single- and double-strand breaks in the DNA backbone, rendering the microorganism unable to replicate or perform vital cellular functions, leading to its death. A major advantage of gamma radiation is its high penetrating power, allowing it to sterilize products that are already sealed in their final packaging, thus preventing recontamination. This is known as terminal sterilization. The process is ‘cold,’ generating very little heat, which makes it suitable for heat-sensitive materials like 塑料, pharmaceuticals, and biological tissues. The dose of radiation delivered is measured in kiloGrays (kGy), and a typical dose for sterilizing medical devices is 25 kGy, which is sufficient to achieve a [latex]10^{-6}[/latex] SAL.

The scientific foundation for this technology was laid by the discovery of radioactivity by Henri Becquerel in 1896 and the subsequent work on radiation’s biological effects. The potential for using ionizing radiation to kill microorganisms was recognized in the early 20th century. However, it wasn’t until the post-World War II era, with the development of nuclear reactors capable of producing large quantities of radioisotopes like Cobalt-60, that industrial-scale gamma sterilization became economically and practically feasible. The first commercial gamma irradiator for medical products was built in the late 1950s. This technology revolutionized the medical supply industry by enabling the reliable, large-scale terminal sterilization of pre-packaged, single-use devices like syringes, sutures, and catheters, which are now ubiquitous in healthcare.