Radio frequency identification (RFID) has been an emerging technology over the past decade with applications ranging from simple supply chain utilizations to sensory monitoring of heat and humidity sensitive products during transportation. RFID has direct implications for the area of pharmaceutical distribution especially for temperature sensitive products where they are tagged and tracked in their shipping environment. Per FDA CPG Sec.400.210, Drugs, Radiofrequency Identification, the FDA has not allowed RFID technology to be used for drugs covered under a Biologics License Application or protein drugs covered by a New Drug Application since the potential impact of radio frequency (RF) radiation on biologics and proteins is not well documented. The intent of this study is to determine the non-thermal effects on the protein structures of biopharmaceuticals by constant exposure to radio frequency energy at different wavelengths using twice the equivalent isotropically radiated power (EIRP) allowed by FCC in the United States. As a contribution of this study, the test setup and protocol provide a fundamental and universally applicable methodology which combine the hardware to generate and radiate high power RF signals at different frequencies and a temperature controlled dark anechoic chamber where the temperature and light sensitive products can be exposed to RF radiation. Five different frequencies are used which account for the majority of commercially available RFID systems adopting high frequency (13.56 MHz) or ultra-high frequency (433 MHz, 868 MHz, 915 MHz, and 2.4 GHz) radio waves as well as active or passive tags for communication. Multiple products from different pharmaceutical companies falling under three major protein groups and their integrity after exposure to 8 Watts EIRP RF radiation for a full 24 hours are investigated. The results show that even at twice the EIRP as regulated by FCC, the effects of RF energy on the purity of all the tested biopharmaceutical proteins remain undetectable after purity and potency stability-indicating assays.
[1]
Apinunt Thanachayanont,et al.
Self-powered wireless temperature sensors exploit RFID technology
,
2006,
IEEE Pervasive Computing.
[2]
D. Archer,et al.
Microwave radiation can alter protein conformation without bulk heating
,
2003,
FEBS letters.
[3]
E Marani,et al.
Future perspectives in microwave applications in life sciences.
,
1994,
European journal of morphology.
[4]
Kai Rothkamm,et al.
Evidence for a lack of DNA double-strand break repair in human cells exposed to very low x-ray doses
,
2003,
Proceedings of the National Academy of Sciences of the United States of America.
[5]
M. de Rosa,et al.
Non‐thermal effects of microwaves on proteins: thermophilic enzymes as model system
,
1997,
FEBS letters.
[6]
J. Kirschvink.
Microwave absorption by magnetite: a possible mechanism for coupling nonthermal levels of radiation to biological systems.
,
1996,
Bioelectromagnetics.
[7]
Daniel W. Engels,et al.
A Method to Investigate Non-Thermal Effects of Radio Frequency Radiation on Pharmaceuticals with Relevance to RFID Technology
,
2006,
2006 International Conference of the IEEE Engineering in Medicine and Biology Society.
[8]
Seth J. Seidman,et al.
An Exposure System for Evaluating Possible Effects of RFID on Various Formulations of Drug Products
,
2007,
RFID 2007.