Karipidis et al. [1] (hereinafter: Karipidis) published a scoping review investigating radiofrequency (RF) studies in the range >6 GHz, with a particular focus on the millimetre wave (MMW) band. The Karipidis review was performed against a backdrop of rising public concerns associated with the health and safety of 5th generation (5G) wireless technology [2]. Subsequently, the telecommunications industry is now using the Karipidis review to suggest “no evidence of adverse health effects from the radio waves used in 5G including mmWave” [3]. Notwithstanding the fact that no studies have investigated specific 5G frequencies and modulations, does the Karipidis review stand up to scrutiny in providing assurances of safety (no evidence of harm) that industry is suggesting? The analysis herein reveals that it does not.
A host of study design weaknesses in the existing literature were critiqued throughout the Karipidis review. In spite of the apparent lack of rigour attributed to many papers, Karipidis concluded that “experimental studies provided no confirmed evidence that low-level MMWs are associated with biological effects relevant to human health” and similarly, that radar-related epidemiological studies “presented little evidence of an association between low-level MMWs and any adverse health effects”.
This line of reasoning parallels that used previously by scientists working for the tobacco industry, whose studies repeatedly arrived at conclusions suggesting no clear determination of harm could be made [4]. This was part of a broader strategy of manufacturing doubt about the potential negative health effects of their product, as summarised by Gilbert [5]:
“The very nature of scientific exploration is to ask and answer the next question. But rather than accepting the process of scientific discovery, business interests press to have every tiny bit of uncertainty explored before any policy decision can be made, demanding proof rather than precaution—in fact, they even manufacture uncertainty. As a result, decisions are not made; policy is not advanced; problems are not addressed.”
A similar ethos is observed with the handling of scientific evidence by some governments and associated regulatory bodies in regards to radiofrequency exposures and health risks [6, 7]. The same was noted by the US Court of Appeals in the recent case against the FCC [8].
Surprisingly, the Karipidis review did not identify and discuss potential risk implications. This is of significant importance, because as Karipidis noted, the use of RF frequencies above 6 GHz is only just beginning. Best practice demands a risk management approach for the identification of all potential hazards and implementation of mitigation strategies to address these risks. This is already the case with low-dose ionizing radiation [9], but is sorely neglected for non-ionizing RF radiation [10]. Rather than waiting for harm to be established before acting, a precautionary approach to risk management is necessary [6, 11].
Detailed analysis of Karipidis tables and selection of papers
In order to conduct an independent assessment of the Karipidis review, we performed our own literature search using the same international research libraries as Karipidis, and also accessed the Oceania Radiofrequency Scientific Advisory Association (ORSAA) database (ODEB) [12].
To perform our assessment, the Karipidis review was critiqued and classified into different categories as summarised in Tables 1 and 2. The full set of Karipidis tables, our corresponding review comments and analysis can be downloaded from the ORSAA website [13]. The results reveal issues of potential bias as well as questions around the completeness and thoroughness of the work conducted by Karipidis.
Critique summary
Examination of the Karipidis 5G health review reveals many errors in classification and analysis. Some are minor, and although indicating a lack of diligence, they have no substantial implications for the outcomes identified in the papers reviewed. Of much greater concern are the number of misstatements, misclassifications, and exclusions of important findings from sound research.
The Karipidis review is at best a superficial analysis of a restricted set of available publications investigating exposures to radio frequencies in the >6 GHz range. No attempt has been made to understand or reconcile differing study outcomes. Karipidis has simply restated the results for specific endpoints, showing papers that have demonstrated statistically significant effects and those that have not. Divergent findings have been used to suggest ‘inconsistency’ as a problem, thereby diminishing the importance of biological effect findings. In contrast, our assessment [13] provides rational justifications to explain some of the divergent findings. We have also previously discussed a number of physical and biological variables, which underlie the different outcomes from studies investigating biological effects of RF exposures in general [14], and MMW exposures in particular [15]. Karipidis also attributed ‘quality’ deficiencies to a number of studies that are unjustified [13].
A literature search identified a significant number of relevant papers (at least 70 experimental papers and 16 epidemiological papers available from PubMed and ODEB) were missing from the Karipidis collection. These papers cover all major themes presented by Karipidis and more, with the majority showing statistically significant effects. By restricting the paper selection criteria, the balance of evidence can be skewed. A lack of transparency regarding papers found and ultimately discarded by Karipidis means that selection bias cannot be excluded.
Also missing from the Karipidis review is an analysis of potential publication and funding biases, which would allow the reader to assess how such influences affect study outcomes. This is often very obvious. For example, on a related topic, Carpenter [16] found that evidence for magnetic fields increasing the risk of cancer is neither inconsistent nor inconclusive (from government or independent studies), yet almost all industry supported studies fail to find any significant or even suggested associations. A similar industry funding study bias was observed with mobile phones [17].
The biased selections and assessments that have been uncovered in the Karipidis review create an unbalanced view of the science, and skew the final conclusion towards uncertainty. In contrast, when appraising all relevant findings, the evidence found in our review points to risks not fully considered by the International Commission on Non-Ionizing Radiation Protection (ICNIRP) or the Australian Radiation Protection and Nuclear Safety Agency (ARPANSA) in their respective RF guidelines and RF standards. These guidelines do not reflect the current state of scientific knowledge and are based on acute heating protection only [10], which is purely for regulatory convenience. The gulf between thermal and non-thermal evaluative frameworks has previously been discussed [6, 18].
Other important works have been omitted from the Karipidis review. Epidemiological studies suggest that RF exposures from other technologies such as radar are associated with an increased risk of hemolymphatic cancers [19], and experimental studies investigating genotoxicity in blood cells [20] have found the same. Such converging evidence requires an immediate focused investigation into RF bioeffects rather than dismissal. Other health risks potentially linked to RF exposures include pregnancy complications, fertility impairment, testicular cancer and brain cancer. These are identified in our analysis [13] and will be discussed in a future paper.
Other researchers [21] agree that the current peer reviewed science points to “predictable harm to life forms within mixed frequency mesh networks with negative consequences likely over time”. Russell assessed the literature on MMW effects on skin and eyes, the immune system, gene expression, and bacterial antibiotic resistance. Because of the shallow penetration of MMW, the skin and eyes are of significant concern. More than a decade ago, research by Feldman et al. [22] indicated that sweat ducts in the skin could behave as antennas and thus respond to MMW. The same group [23] later stated that there is enough evidence suggesting that helical sweat ducts in conjunction with wavelengths approaching the dimensions of skin layers could lead to non-thermal biological effects.
Finally, the Karipidis review lacks representation of many species, including plants, amphibians, birds, domestic animals and most importantly, insects. Therefore, readers are provided with little to no understanding of how MMWs impact these important ecological entities. This is a significant gap.
Discussion
The above critique of the Karipidis review raises a number of ‘red-flags’. These require clarification and clear justification before telecommunications companies are given carte blanche to begin rolling out novel modulated signals to which biological systems have never been exposed.
Karipidis has conducted an investigation resulting in the exclusion of important findings, while also overemphasising quality deficiencies and inconsistencies in the data, thereby suggesting confirmation bias. Di Ciaula [24] argues that underestimating the relevance of available results (in particular those from in vitro and animal models) is ethically unacceptable, and is equivalent to saying that potential hazardous effects can only be assessed after the agent has had time to exert its harmful effects.
In this regard, Gee’s discussion [25] of risk assessment is pertinent. In “late lessons from early warnings” a variety of case studies spanning chemicals, physical agents, pathogens, and environmental issues illustrate how timing is critical for risk analysis and application of the precautionary principle. In all cases, precautionary action, or foresight based on a lower strength of evidence, would have lowered the burden of disease, reduced unnecessary suffering and prevented many premature deaths.
Conclusion
In our opinion, the Karipidis review provides insufficient evidence of safety, which is being used by Industry [3] as justification for the planned densification and ubiquitous use of radiofrequencies >6 GHz as part of the 5G rollout. However, we concur with Karipidis that future experimental studies “should improve the experimental design” and “epidemiological research should continue to monitor long-term health effects in the population related to wireless telecommunications”.
The Karipidis review seemingly equates risk management with the need to confirm evidence of harm. The point at which harm becomes a public issue is far too late, given the size of the population being exposed without formal consent. We consider that risks to humans and the environment identified in past epidemiological studies [13], as well as unknown risks yet to be identified, warrant the application of a precautionary approach.
We find the Karipidis review to be both inadequate and incomplete, sending the wrong messages regarding safety assessment and public health.
Data availability
Data generated and analysed for the production of this comment article is freely available for download from the Oceania Radiofrequency Scientific Advisory (ORSAA) website at the following address: https://www.orsaa.org/5g-review-supplementary-material.html.
References
Karipidis K, Mate R, Urban D, Tinker R, Wood A. 5G mobile networks and health-a state-of-the-science review of the research into low-level RF fields above 6 GHz. J Expo Sci Environ Epidemiol. 2021;31:585–605.
Parliament of Australia. Committee Inquiry into 5G in Australia. https://www.aph.gov.au/Parliamentary_Business/Committees/House/Communications/5G/Submissions Accessed 28 September 2022.
Telstra. 5G and EME research. 2021. https://www.telstra.com.au/consumer-advice/eme/5g-and-eme [Under heading “5G and EME Research” (paragraph 4)] Accessed 28 September 2022.
Brandt AM. Inventing conflicts of interest: a history of tobacco industry tactics. Am J Public Health. 2012;102:63–71.
Gilbert SG. Doubt is their product: how industry’s assault on science threatens your health. Environ Health Perspect. 2009;117:A218.
Weller S, Leach V, May M. Comment on letter: “Post-normal science and the management of uncertainty in bioelectromagnetic controversies” by A.W. Wood. Bioelectromagnetics. 2020;41:80–4.
Alster N. Captured Agency: How the Federal Communications Commission Is Dominated by the Industries It Presumably Regulates. Edmond J. Safra Center for Ethics, Harvard University, Cambridge, MA; 2015.
Environmental Health Trust et al. vs Federal Communications Commission and United States of America. https://www.cadc.uscourts.gov/internet/opinions.nsf/FB976465BF00F8BD85258730004EFDF7/$file/20-1025-1910111.pdf Accessed 28 September 2022.
ICRP. 2007. The 2007 Recommendations of the International Commission on Radiological Protection. ICRP Publication 103. Ann. ICRP 37 (2–4).
Hardell L. World Health Organization, radiofrequency radiation and health - a hard nut to crack (Review). Int J Oncol. 2017;51:405–13.
Leach V, Bromwich D. Why the precautionary approach is needed for non-ionising radiation devices. Radiat Prot Australas. 2018;35:13–21.
Leach V, Weller S, Redmayne M. A novel database of bio-effects from non-ionizing radiation. Rev Environ Health. 2018;33:273–80.
ORSAA. A critical analysis of Karipidis 5G Health Review. 2022. https://www.orsaa.org/5g-review-supplementary-material.html Accessed 28 September 2022.
Belyaev IY. Dependence of non-thermal biological effects of microwaves on physical and biological variables: implications for reproducibility and safety standards. Eur J Oncol. 2010;5:187–218.
Belyaev IY, Shcheglov VS, Alipov ED, Ushakov VD. Nonthermal effects of extremely high-frequency microwaves on chromatin conformation in cells in vitro - Dependence on physical, physiological, and genetic factors. IEEE Trans Micro Theory Tech. 2000;48:2172–9.
Carpenter DO Extremely low frequency electromagnetic fields and cancer: How source of funding affects results. Environ Res. 2019; 178: https://doi.org/10.1016/j.envres.2019.108688.
Huss A, Egger M, Hug K, Huwiler-Muntener K, Roosli M. Source of funding and results of studies of health effects of mobile phone use: systematic review of experimental studies. Environ Health Perspect. 2007;115:1–4.
Belyaev I Main regularities and health risks from exposure to non-thermal microwaves of mobile communication. In: 14th International Conference on Advanced Technologies, Systems and Services in Telecommunications (TELSIKS), Nis, Serbia IEEE. 2019. 111-6. https://doi.org/10.1109/TELSIKS46999.2019.9002324.
Peleg M, Nativ O, Richter ED. Radio frequency radiation-related cancer: assessing causation in the occupational/military setting. Environ Res. 2018;163:123–33.
Zaroushani V, Khavanin A, Mortazavi SB. Nonthermal effects of radar exposure on human: a review article. Iran J Health Saf Environ. 2014;1:43–52.
Russell CL. 5 G wireless telecommunications expansion: Public health and environmental implications. Environ Res. 2018;165:484–95.
Feldman Y, Puzenko A, Ben Ishai P, Caduff A, Agranat AJ Human skin as arrays of helical antennas in the millimeter and submillimeter wave range. Phys Rev Lett. 2008; 100: https://doi.org/10.1103/PhysRevLett.100.128102.
Betzalel N, Ben Ishai P, Feldman Y. The human skin as a sub-THz receiver – Does 5G pose a danger to it or not? Environ Res. 2018;163:208–16.
Di Ciaula A. Towards 5G communication systems: are there health implications? Int J Hyg Environ Health. 2018;221:367–75.
Gee D. Late lessons from early warnings: towards realism and precaution with EMF? Pathophysiology. 2009;16:217–31.
Wood A, Mate R, Karipidis K. Meta-analysis of in vitro and in vivo studies of the biological effects of low-level millimetre waves. J Expo Sci Environ Epidemiol. 2021;31:606–13.
Acknowledgements
We would like to acknowledge Professor Cordia Chu, director at Griffith University, School of Medicine and Dentistry, who provided invaluable advice in the development of this paper.
Author information
Authors and Affiliations
Contributions
SW was responsible for reviewing and categorising all Karipidis research articles, writing the analysis documents and initial comment letter. MM and JM offered feedback, and further contributed to writing of letter content and adding references. VL provided ORSAA database relevant records, offered feedback and further contributed to letter content. DP offered feedback and advice on epidemiological studies. IB contributed to letter content, provided feedback and contributed to the analysis documents.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interest. SW, VL and JM are founding members of ORSAA. This association is a not-for-profit scientific advisory association and not an advocacy group for any specific cause. ORSAA derives income from public donations and has no ties with industry or government. IB provided an expert opinion in the Cell Phone Litigation on the link between microwave radiation and human health.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Weller, S., May, M., McCredden, J. et al. Comment on “5G mobile networks and health-a state-of-the-science review of the research into low-level RF fields above 6 GHz” by Karipidis et al.. J Expo Sci Environ Epidemiol 33, 17–20 (2023). https://doi.org/10.1038/s41370-022-00497-8
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/s41370-022-00497-8