For Residents

Nanotechnology: Why Should We Care?

Am J Orthop. 2015 March;44(3):E87-E88

References

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Major limitations regarding successful clinical implementation of nanotechnology include both cost and regulatory processes. Currently, pharmaceutical companies estimate that, on average, successful clinical trials from phase 1 to completion for new drugs can cost hundreds of millions of dollars.²³ Such high costs result partially from the laborious and capital-intensive process of conducting clinical trials that meet US Food and Drug Administration (FDA) requirements. These regulations would apply to both surface-coated implants and nanoparticle-based drug delivery systems. These types of implants would not be expedited into the market secondary to their drug delivery component and would likely require lengthy clinical studies. Implant companies may be reluctant to invest millions of dollars in multiple FDA trials when they have lucrative implants on the market.

Other limitations include the particles’ complex 3-dimensional structure, which can present challenges for mass production. Producing large quantities of nanoparticles at a consistent quality may be a major limitation to the more unique and target-based nanotherapies. Recent concerns with the toxicity profile of nanotechnology-based medicines have resulted in more intense scrutiny of the nanotechnology safety profile.^24,25Currently, nanoparticle technology is evaluated case by case with each technology requiring its own toxicology and safety profile testing if it is intended for human use. These tests can be cost-prohibitive and require extensive private and government capital for successful market entry. Despite these limitations, nanotechnology will impact the next generation of orthopedic surgeons. Current estimates project the nanomedicine market to be worth $177.6 billion by 2019.²⁶

Advances in nanobased orthopedic technologies have expanded dramatically in the past decade, and we, as the treating physicians, must make educated decisions on how and when to use nanoparticle-based therapies and treatment options. Nanotechnology’s basic science is confusing and often burdensome, but contemporary review articles may be helpful in keeping the orthopedic resident and clinician current with advancements.^10,27,28 The more we educate ourselves about evolving nanotechnologies, the less reluctance we will have when evaluating new diagnostic and therapeutic treatment modalities.