June 17, 2014
A nanoshell to protect foreign enzymes used to starve cancer cells as part of chemotherapy has been developed by nanoengineers. Enzymes are naturally smart machines that are responsible for many complex functions and chemical reactions in biology. However, despite their huge potential, their use in medicine has been limited by the immune system, which is designed to attack foreign intruders.
The shell’s pores are too small for the enzyme to escape but big enough for diffusion of amino acids that feed cancer cells in and out of the particle. The enzymes remain trapped inside where they deplete any amino acids that enter.
A nanoshell to protect foreign enzymes was used to starve cancer cells as part of chemotherapy.
Enzymes are naturally smart machines that are responsible for many complex functions and chemical reactions in biology. However, despite their huge potential, their use in medicine has been limited by the immune system, which is designed to attack foreign intruders. For example, doctors have long relied on an enzyme called asparaginase to starve cancer cells as a patient undergoes chemotherapy. But because asparaginase is derived from a nonhuman organism, E. Coli, it is quickly neutralized by the patient's immune system and sometimes produces an allergic reaction. In animal studies with asparaginase, and other therapeutic enzymes, the study found that their porous hollow nanoshell effectively shielded enzymes from the immune system, giving them time to work.
Asparaginase works by reacting with amino acids that are an essential nutrient for cancer cells. The reaction depletes the amino acid, depriving the abnormal cells from the nutrients they need to proliferate.
It’s is a pure engineering solution to a medical problem.
The nanoshell acts like a filter in the bloodstream. The enzymes are loaded into the nanoparticle very efficiently through pores on its surface and later encapsulated with a shell of nanoporous silica. The shell's pores are too small for the enzyme to escape but big enough for diffusion of amino acids that feed cancer cells in and out of the particle. The enzymes remain trapped inside where they deplete any amino acids that enter.
This is a platform technology that may find applications in many different fields. The starting point was solving a problem for cancer therapeutics.
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