Consider the woodpecker: The contested more-than-human ethics of biomimetic technology and traumatic brain injury

Why don’t woodpeckers get headaches?

Around the same time as Mike Webster’s death in 2002, Ivan Schwab, an ophthalmologist based at The University of California at Davis, published an article entitled ‘cure for a headache’ that graced the pages of the British Journal of Ophthalmology (Schwab, 2002). As editor of the journal, Schwab was also able to ensure that a picture of the bird appeared on the issue’s front cover (Nadis, 2006: 616). In the article, as well as in his later textbook Evolution’s Witness, Schwab (2012) addresses the apparently perplexing question of why woodpeckers don’t get headaches. Woodpeckers are tree-dwelling birds found across much of the planet and are perhaps most notable for their eponymous behaviour: drumming on tree trunks in order to feed on insects beneath the bark and communicate with other birds. Focusing on the pileated woodpecker (Dryocopus pileatus) found in North America, Schwab observes that the bird:

may strike the hard surface of a tree at a rate of up to twenty times a second (not a misprint) and up to 12,000 times a day, with deceleration forces of up to 1200 grams with each impact. That’s the equivalent to striking a wall at 16 miles an hour – face first – each time. (Schwab, 2012: 198)

In both the article and the textbook, Schwab details a number of evolutionary adaptations which mitigate against the potentially problematic repercussions associated with hitting a wall, face first, 12,000 times a day – problems which might include retinal detachment, concussion, headaches and the eyes ‘quite literally popping out of the woodpecker’s head’ (Schwab, 2002: 843).

The woodpecker’s adaptions, suggests Schwab, are numerous and remarkable (pp. 198–199). Amongst others, these adaptations include a subarachnoid space that contains little cerebrospinal fluid and that allows the brain to be ‘tightly packed’ within the skull and, perhaps most spectacularly, a tongue that

passes through the right nostril, between the eyes, divides into two, arches over the superior portion of the skull and around the occiput [back of the head] passing on either side of the neck, coming forward through the lower mandible, and uniting into a single tongue in the oropharyngeal cavity … [in order to] create a curious sling-like structure that probably functions as an isometric shock absorber …. (Schwab, 2002: 843)

These adaptions, and the tongue in particular, are sometimes described as giving the woodpecker a natural ‘safety belt’ for its brain (e.g. Wang et al., 2011: 7).

In 2006, ‘Cure for a headache’ would win Schwab an Ig Nobel award, jointly shared with Phillip May, who had undertaken research into the topic several decades before (e.g. May et al., 1976, 1979), and received while wearing a ‘woodpecker headdress’, that is, a bicycle helmet topped with a yellow beak and large red plume. Ig Nobel prizes are awarded ‘for achievements that first make people LAUGH then make them THINK’ (Ig Nobel Prizes, n.d., emphasis in original) and, to this end, it is perhaps noteworthy that an article in Nature discussing Schwab’s win describes awardees as ‘embarrassed’ (Nadis, 2006 617), while a piece in The Telegraph lists Schwab’s study in an article entitled ‘Pointless research: Top 10 Ig Nobel award winners for silly science’ (Chivers, 2009). Significantly, the general merriment at the Ig Nobels is matched by the jovial tone in Schwab’s article and all of which suggests that, circa 2002–2006, his research into woodpeckers was deemed by all involved to be little more than a curiosity, something to induce a laugh only to be followed, possibly, and if we’re generous, by a moment’s reflection on the wonder of evolution.

Regardless of its intention, Schwab’s work and award appears to have given knowledge of the woodpecker’s resilience to headaches something of a boost. Alongside significant media coverage, citations to both his own and May’s work from the 1970s increased significantly, ³ as did an emergent academic field looking into the matter. A book for birdwatchers entitled Why Don’t Woodpeckers Get Headaches was released in 2007 (O’Connor, 2007) and woodpeckers’ special abilities even got a mention in the 2019 Lion King remake. ⁴ What was absent from these wide-ranging discussions in the wake of Schwab’s work, however, was any mention of the ‘concussion crisis’ which by 2006 was engulfing American Football in the wake of Mike Webster’s death. The brain damage of Mike Webster and the apparent lack of brain damage in the head-banging woodpecker were left unconnected.

Woodpecker brains and human remains

At the time of Schwab’s Ig Nobel award there were, in fact, occasional moments when it appeared as if knowledge about humans and woodpeckers might be drawn together. Steve Nadis, writing in Nature, says that like ‘boxers, woodpeckers tense their neck muscles before absorbing a blow’ (Nadis, 2006: 616). In other words, humans and woodpeckers may be alike in being able to mitigate against acute head injury. Several years later, however, quite a different message was taken from the case of the woodpecker – perhaps most notably through the 2015 film Concussion (Landesman, 2015).

Starring Will Smith as Omalu; David Morse as Webster; and Alec Baldwin as Julian Bailes, a well-known neurosurgeon and former doctor to the Pittsburgh Steelers, Concussion is a fictionalized retelling of the story underpinning the introduction this essay – Omalu’s (re)discovery of CTE. The film occupies a central place in ongoing discourse about CTE: It has prompted articles in The Lancet Neurology (Smith and Stewart, 2016), while social scientists have argued that it has ‘solidified star status for the fragile brain’ (Martin and McMillan, 2020: 2). Alongside League of Denial, the film is understood as one of the ‘key media texts’ to have ‘crucially shaped’ the ‘underlying tone of media coverage about CTE’ (Ventresca, 2019: 143). Gallup analysts have gone so far as to suggest that the film may be responsible for a slight decrease in the popularity of the NFL (Sandel, 2020: 170). At the centre of Concussion is the assertion that the NFL knew that football caused brain damage and, fearing the economic consequences of CTE, actively attempted to cover up Omalu’s findings in a manner akin to the tobacco industry’s cover-up of the dangers of smoking. ⁵

Concussion features woodpeckers as a reoccurring motif, moving them into an earnest position at the very centre of Webster’s self-evidently serious story. Around twenty minutes into the film there is a tense meeting between Bailes and Webster. Morse plays Webster as distressed and agitated throughout this meeting. The pair discuss Webster’s medication and Webster pleads with Bailes for help, asking the doctor to ‘fix this’, while grabbing his head. Bailes eases Webster into a seat, giving him a shot of the antipsychotic drug Haldol as he does so. Webster receives this injection from Bailes in the background of the shot while, sitting on Bailes’ desk, in the foreground and for 5 seconds, is a woodpecker skull complete with the safety belt tongue.

While the presence of the skull is not remarked upon in this scene, later, after Webster’s death and the posthumous diagnosis by Omalu, the bird is explicitly drawn upon. In this scene, Omalu tries to explain to his colleagues how football could have damaged Webster’s brain. He reaches into his briefcase for a manilla folder that, upon opening, reveals some pictures of animals. Omalu explains the pictures to his colleagues:

The Cape Gannet, a diving bird capable of generating speeds of up to 75 miles per hour, turning itself into a missile as it collides into the face of the sea. The Red Head Woodpecker can absorb a g-force of 1000, pecking a tree 12,000 times a day, 85 million times over its lifetime. Big Horn Sheep can generate… [Omalu is cut off at this point by his understandably frustrated colleagues]. Okay, okay. All of these animals have shock absorbers built into their bodies. The woodpecker’s tongue extends through the back of the mouth, out of the nostril, encircling the entire cranium. It is the anatomical equivalent of a safety belt for its brain. Human beings, not a single piece of our anatomy protects us from those types of collisions. A human being will get concussed at 60 Gs. A common head-to-head contact on a football field? 100 Gs. God did not intend for us to play football. (Landesman, 2015, emphasis in original)

The language is strikingly similar – the 12,000 hits a day, the anatomical description of the safety-belt tongue – to that of Schwab during his more light-hearted discussions of the woodpecker.

Both of these scenes from Concussion are, in some respects, tethered to non-fiction. The preface to Omalu’s (2017) autobiography, Truth Doesn’t Have a Side, is entitled ‘God did not intend for human beings to play football’ and in that preface Omalu (2017) states ‘Woodpeckers can play football safely. Humans cannot …’ (p. 14). League of Denial also suggests that Bailes did indeed display ‘a woodpecker skull in a jar on top of his desk. … Every once in a while, someone ask Bailes about the curious object. … He would pick up the tiny bird brain … and explain that if only NFL players were built like woodpeckers, none of this would have happened’ (Fainaru-Wada and Fainaru, 2013: 2).

It is evident from Concussion that woodpeckers are being positioned to have an important rhetorical function in the story of CTE. Indeed, and while this work is going on at quite some distance from the laboratory (Asdal, 2008), I suggest that the woodpecker is being introduced to scaffold a particular understanding of CTE and that this scaffold is intended to support both an epistemological and an ethical argument.

Unlike the mice examined by Nelson, where modelling was based upon a form of ‘transposition’ (Friese and Clarke, 2012) wherein the bodies of mice and humans are understood to be in important respects analogous, woodpeckers become entangled with the narrative of Webster’s CTE while, materially, remaining distant from it. If, as Phillip May said in the 1970s, woodpeckers are an ‘experiment in Nature’ (May et al., 1976: 454), then I suggest that they are deployed in order to demonstrate three matters simultaneously.

First, human anatomy is understood here to be of a profoundly, irrevocably different nature to that of the woodpeckers. These are two species who resolutely do not meet. Daston has identified one primary use of the word ‘nature’ to be what she calls ‘specific natures’ – the traits ‘which makes it [an organism] what it is and not something else, its ontological calling card’ (Daston, 2019: 7). The demarcation of ‘species’ as part of taxonomic ordering is a primary science of ‘specific natures’, according to Daston, with the label denoting that organisms of different species necessarily have different specific natures. Given that they are evidently different species, it is perhaps unsurprising that woodpeckers and humans are articulated here as radically discontinuous from each other. Nonetheless, and as Friese and Clarke (2012) discuss, acts of generalization and standardization across species boundaries necessarily lie at the heart of work which uses animal models as part of their epistemic scaffolding (see also: García-Sancho and Myelnikov, 2019). The woodpecker, by contrast, is introduced to play a quite different role: they demonstrate not that a trait is generalizable across species, but precisely the opposite. The specific nature of the woodpecker includes ‘shock absorbers’, unlike that of the human.

Second, football is profoundly unnatural, at least for humans. A second use of ‘nature’, according to Daston, is ‘local nature’ – ‘a harmony between people, climates, topographies, and laws … the elements of each formed a harmonious (and sometimes precarious) whole, poised in delicate equilibrium’ (Daston, 2019: 16, 19). Certain species, then, belong in certain spaces and as part of certain ecologies. When Omalu (2017) tells us that ‘[w]oodpeckers can play football safely. Humans cannot’ (p. 14) and Bailes laments that ‘if only NFL players were built like woodpeckers, none of this would have happened’ (Fainaru-Wada and Fainaru, 2013: 2) they draw attention to this point. For these protagonists, it is not that the ecology of the football field per se is pathological, it is that humans are in a state of disequilibrium (Daston, 2019: 19) while occupying it. Juxtaposing humans with woodpeckers, who remain in a state of equilibrium within their own head-banging ecological setting, demonstrates this point.

The third rhetorical usage of woodpeckers in the above passages most clearly demonstrates that the scaffold work being performed by woodpeckers is best understood as ethico-epistemic in nature. The prologue to League of Denial – the keystone cultural text, alongside Concussion, about the discovery of CTE (Furness, 2016; Ventresca, 2019: 143) – is entitled ‘bird brains’, a term that also appears in medic Elizabeth Sandel’s recent book Shaken Brain (Sandel, 2020: 17). ‘Bird brain’ is a phrase for stupidity which has been widely used since at least the 19th century (Emery, 2016: 17) and its use in League of Denial as an introductory framing device makes explicit a dimension of the discussion which otherwise remains unsaid but lurks in the background throughout: Woodpeckers demonstrate just how ludicrous it is to think that the human body would ever be able to tolerate the kind of forces involved in playing a game like football. The disequilibria caused by a human on a football field should be obvious. ‘God did not intend’ for us to be in this space, Omalu states, so organizations like the NFL put players like Webster at risk against the will of God. Leading cultural texts, including those produced by scientists like Omalu, therefore seek to deploy the woodpecker as a ‘persuasive object’ that weaves together epistemological and ethical arguments that both exemplify the costs of football on the human brain and seek to ‘convince and compel’ a future course of action (Roosth, 2017: 175–176).

The centrality of American football to the lives and livelihoods of so many means that suggesting American football needs to be radically overhauled, maybe even banned, ⁶ is a claim likely to be vigorously contested. Indeed, Bachynski (2019) has argued that even well into the 2010’s ‘[f]undamentally altering, let alone eliminating, the sport of football was largely not part of the framework advanced by those seeking policy changes to improve sports safety’ (p. 200) while research suggests communities most invested in football are slower to pass concussion safety laws (Rotolo and Lengefeld, 2020). I suggest here that key texts, such as League of Denial and Concussion, which can be seen as advocating more radical change, scaffold that ethico-epistemic argument, in part, through the radical alterity of the woodpecker.

Nature tells us there is a solution

‘While human anatomy clearly differs from that of the woodpecker’, states an article from 2012, ‘some correlates do exist in the prevention of TBI’ (Turner et al., 2012: 1111). There is already a hint in this passage that the author of these words sees not an abyssal chasm between woodpeckers and humans, but bridges waiting to be crossed. As did Steve Nadis in the aforementioned Nature report on the Ig Nobels, Turner et al. turn to boxing to elucidate these possibilities:

Professional boxers are capable of sustaining forces of great magnitude when preparing for the impact. … Much of this protection has been attributed to a tightening of the neck muscles, one of which is the omohyoid muscle. (Turner et al., 2012: 1111)

Despite this shared ability to tighten the omohyoid muscle, at least two problems remain. First, prior to, say, a blindside hit on a football field, few of us humans are able to prepare for impact in the manner of a boxer (or, indeed, a woodpecker). Second, and the near century long articulation of ‘punch drunk syndrome’ attests to this fact (Casper, 2018a: 10), boxers do still get headaches and much worse besides. The capacity of humans to withstand head trauma, even when prepared, is evidently a long way from sufficient.

In a promotional video released some years later, Smith, an author on the 2012 article, explains what he sees as the fundamental problems with human physiology:

When the brain is able to move it is similar to being inside of a car and having your seatbelts not tightened. In traumatic brain injury the brain is able to actually move within its cranial space. We oftentimes refer to this as slosh. (Q Collar Canada, n.d.)

As did Omalu, Wang and others, Smith again here turns to the notion of a ‘seatbelt’ – absent, it seems, in humans – in order to understand brain injury. Smith gives this information via a talking-head interview before the screen cuts to the head and shoulders of a computer-generated skeleton with a brain banging around inside the skull. Over the image is written ‘Slosh (släSH) noun. The movement of the brain in the cerebral spinal fluid of the cranium’. This term ‘slosh’, far from being a dictionary definition, was first applied to brain movement by Smith himself, taking it from NASA’s studies of rocket propellants (Turner et al., 2012: 1111).

If the ability to ‘tighten’ the hyoid muscle is thus a point of similarity between woodpeckers and humans, then the fact that the woodpecker’s tongue and hyoid bone constitute a ‘muscular sling’ – an effective safety belt – is an obvious point of difference. It is the goal of the authors to overcome that difference. Smith et al. (2012) suggest that:

Because of the direct proximity of the omohyoid atop of the IJVs [Internal Jugular Veins], it is intriguing to speculate that, on contraction of the omohyoid, perhaps with each peck, the IJVs may be partially occluded and intracranial compliance exhausted (p. 745)

In other words, the woodpecker’s omohyoid muscle ‘may’ partially obstruct the jugular vein, reducing blood flow from the head, increasing the volume of blood within the intracranial space, and thus reducing ‘slosh’ and subsequent brain trauma. However, whereas Omalu – in both the laboratory and in Hollywood – uses this physiological difference to construct an ethico-epistemic scaffold which definitively divided humans and woodpeckers, these authors see a possibility for mimicry and entanglement. The stated goal of the research group is to artificially induce physiological changes found in the woodpecker in other species, and they are intent on ‘biology-inspired discovery’ (Smith et al., 2012: 744) in relation to brain trauma.

One of the articles published in 2012 (Smith et al., 2012: 745) shows a white lab rat, hanging onto a beam and wearing a ‘jugular vein compression device’, a blue collar which fits like a choker necklace. The intent of this collar is ultimately to reduce brain injuries in the rats by narrowing the great divide with woodpeckers. The collar seeks to mimic an aspect of the woodpecker’s physiology discussed above: By applying extra pressure on the jugular vein, it is hoped that the collar reduces slosh in the rat brain, mimicking the neurophysiology of the woodpecker, and affording the animal some protection against head injury.

The authors fitted a small number of lab rats with collars while a 450-gram brass weight was dropped onto prone animals, half of whom had been fitted with the jugular compression collar. When the rats were killed a week later and examined for axonal brain injury, the animals wearing collars were found to have significantly fewer amyloid precursor proteins – implicated in dominant theories of Alzheimer-like dementias (Lock, 2013: 65) – in their brains (Smith et al., 2012; Turner et al., 2012). These rats, as surrogate humans, made to mimic woodpeckers, offered the possibility of reducing brain injury in those liable to suffer brain trauma.

Over the following ten years, up to and including the present moment, the research group would publish dozens of articles, patents and publicity materials associated with the slosh theory of concussion and the collar as a mode of mitigation. Smith had co-founded ‘TBI Innovations’ in 2011 (the conflict of interest is noted on both 2012 publications) and in time a collar based upon that trialled in the rats would be sold, first by Bauer Hockey under the name ‘Neuroshield’ and then by Q30 Innovations under the name ‘Q-Collar’. This collar would go on to win industry prizes – The Industrial Designers Society of America awarded the Q-Collar a ‘gold’ award in their ‘Sport, leisure and recreation’ category, stating: A ‘revolutionary approach to protecting the brain, Q-Collar addresses the problem from the inside out by mimicking the natural defense used by woodpeckers’ (Industrial Designers Society of America, 2017). The collar was made available to purchase in Canada in 2019, the United States in 2021, and with the promise of imminent expansion into Europe. The collar currently retails at C$249/US$199 (approximately €170; £145 at time of writing) and has been worn by both amateur and professional athletes, including a number of players in the NFL (Person, 2018). The Q-Collar, then, is a biomimetic object which has captured a degree of media, industry, scientific and sporting attention. And across these diverse sites the woodpecker scaffolds the Q-collar as an origin story, a bio-mimetic inspiration, a marking tool, an award rationale and as a hook in the popular press.

The animals in the market

Getting the Q-Collar to market required the enrolment of a huge number of animals variously related to humans as synonym or antonym, sibling or separate, worthy of saviour or worthy of sacrifice. ⁷ The efficacy of the collar would be tested on pigs who, like the rats, similarly suffered experimentally-induced brain trauma while fitted with collars and, again like the rats, demonstrated reduced evidence of neuropathological lesions (Mannix et al., 2020; Sindelar et al., 2017). Like Nelson’s rats, these are sacrificial animals (Lynch, 1988) understood as being, in important ways, like humans and thus able to stand in as surrogates.

Quite differently, patent applications from across the time period (e.g. Smith et al., 2014b: 25, 2019: 22) suggest that the Q-Collar might be fitted to protect certain dogs, which are also assumed to be like humans but evidently have different ethical standings than pigs and rats. Noting that smell is often compromised after a brain injury, the patent applicants argue that concussive

injury to Breecher dogs (e.g. bomb sniffers) can be catastrophic. Breecher dogs are inherently exposed to the risk of concussive events and their primary purpose is to help soldiers avoid such an event. Preventing or reducing the likelihood of TBI and associated loss of smell can be critical to the Breecher dog’s mission. (Smith et al., 2014b: 25)

While it is evident that the primary market envisioned for the Q-Collar is the sports market, the possibility that collars might be fitted to both humans and nonhumans at war is thus given serious consideration. Such consideration seems logical given that, and as noted earlier, the military are the most significant funders of biomimetic research and also fund research into concussion and football. ⁸ The specifics of the Q-Collar differ from examples which underpin much existing scholarship on biomimicry – such as the ‘robo-lobster’ (Johnson, 2020) or ‘artificial dragonfly’ (Masco, 2006: 322) – inasmuch as the Q-Collar acts to append, rather than replace, human and nonhuman actors in the battlefield. What the Q-Collar has in common with the above examples, though, is its envisaged enrolment within existing institutions and practice.

Despite ongoing concern with dogs and pigs, it is those species that hold biomimetic potential that sustain the most attention. The ‘head ramming sheep’, mentioned in the film Concussion alongside the woodpecker, for example, makes a reappearance. Writing in the New York Times in an article called ‘Can animals help limit concussions?’, Myer understands the sheep as an animal that can self-induce physiological effects to protect itself from concussion, stating that

the sheep has hollow pneumatic horn cores attached to its respiratory system that allow it to re-breathe its air and thus increase carbon dioxide in its bloodstream, expanding its intracranial vascular tree and enhancing the Bubble Wrap effect. (Myer, 2014)

In an academic context, Myer et al. (2014) re-assert this claim, positioning the sheep alongside the woodpecker as offering a biomimetic solution to brain injury (p. 165). A number of patent applications also spend a significant amount of time discussing the capacity of CO₂ to modulate the degree of slosh (e.g. Smith, 2018: 4–6; Smith et al., 2014a: 25), taking their lead from sheep physiology. Despite this, interviews with Smith suggest that artificially increasing levels of CO₂ have been discarded as a biomimetic possibility (Wheeler, 2017).

The woodpecker, meanwhile, is discussed in nearly every patent application, including the most recent (e.g. Smith et al., 2019). As is the case in some of the published literature (e.g. Smith et al., 2012: 745), the bird is marshalled somewhat flexibly in these patent applications, with the biology purportedly mimicked shifting slightly – perhaps an inspiration rather than original (Fisch, 2017). Rather than an exclusive focus on the possible contraction of the omohyoid muscle in order to increase intracranial pressure, the authors on occasion – and as far back as at least 2014 (e.g. Smith et al., 2014a) – state that ‘it is known that the woodpecker has a “pectin [sic] apparatus” that protects the globe of the eyeball from the 1200 G impact of pecking’ (Smith et al., 2019: 27). This phrasing suggests that it is the woodpecker’s mode of eye protection being mimicked. In the very next paragraph, though, the authors return to noting that the device sold as the Q-Collar ‘raises intracranial volume and pressure and/or intraocular pressure’ (Smith et al., 2019: 27) and published research continues to emphasise that woodpeckers may increase their intracranial pressure/volume via the jugular vein (e.g. Myer et al., 2016: 2). Across sources, it is the capacity of the woodpecker to modulate pressure/volume which is mimicked.

Woodpeckers are, however, rarely mentioned in scientific publications since 2016. These are publications that seek to demonstrate the utility of the collar for reducing neurotrauma, not only in rats and pigs, but in humans acting in settings ranging from military drills (Bonnette et al., 2018; Yuan et al., 2019); to American football (Myer et al., 2016; Yuan et al., 2017, 2018a); to soccer (Myer et al., 2019; Yuan et al., 2018b). Nelson suggests that, once work is complete, the ‘scaffold is dismantled’ (Nelson, 2013: 7) and evidence of its presence disappears. The reduced visibility of the woodpecker within scientific publications can be read in such terms.

In publicly facing material, though, the woodpecker remained strikingly present after the Q-Collar was re-launched by Q30 Innovations in 2019. In a video notable only for its typicality, and after Smith and Julien Bailes ⁹ have described the problems caused by brain slosh, a voiceover states that ‘Nature tells us that there is a solution’. The video cuts, with the sound ramped up to a deafened thud, to sheep butting heads and a woodpecker pecking. The camera returns to Smith, who states that:

The head-ramming sheep and the woodpecker; both of these animals have these muscles in their neck called an ‘omo’ which stands for shoulder hyoid muscle and it actually compressed the vasculature of the neck and creates a change in how fast fluids are able to get back out of the brain space.

The image on screen cuts between Smith offering a description of the muscle in question and footage of pileated woodpeckers and rams. A voiceover offers that ‘Now, Q30’s Q-collar brings this breakthrough technology to all sports venues’ (Q Collar Canada, n.d.).

Across patents, publications and publicity materials, the woodpecker is put to work here in ways that are starkly different from the narratives told by those who use woodpeckers to elucidate their horror at the disequilibria of the football field and the damage to players like Mike Webster. While the framing that ‘nature tells us there is a solution’ seems to reinforce the nature-society dichotomy (see: Fisch, 2017), this is at least partially undercut by the insistence on shared physiology in the form of the omohyoid muscle, the jugular vein and the susceptibility to ‘slosh’.

The differences between woodpeckers and humans – so crucial to the ethico-epistemic scaffold of Omalu et al. and detailed above – are overcome biomimetically, shifting the specific nature of the human (and at various points the rat, and the pig, and the dog) so that it becomes one with the woodpecker. This erosion of difference facilitates a process of ‘transposition’ and the ‘back and forth relationships between different lines of work, different spaces and different species’ bodies’ evident in much animal modelling (Friese and Clarke, 2012: 34). By mimicking the physiology of the woodpecker, the human is made to be at home, and in a state of equilibrium, on both the football and the battle-field.

An important consequence follows from this novel articulation of the woodpecker. The ethico-epistemic project of Omalu et al. – premised upon the disentanglement and the radical alterity of humans and woodpeckers – scaffolded a straightforward solution to CTE and the death of players like Mike Webster: Stop playing football. Abandon this cultural practice. The ‘solution’ that Q-Collar offers is evidently quite different: A safer but fundamentally unaltered sport. This is the entire goal of the project. It is the nature-culture hybrid, the entangled biomimetic posthuman, who stands with continuity and the status quo.

What is it like to be a woodpecker?

This rearticulation of the woodpecker as an epistemological support for the Q-Collar requires a lot of scaffolding. At a minimum, four more-or-less independent scaffolds are essential: (i) The ‘slosh theory’ of concussion that suggests that it is movement within the skull that results in brain damage; (ii) The ‘de-sloshed’ woodpecker that suggests that woodpeckers don’t get headaches because their specific nature (e.g. their seat-belt tongue) ensures that their brain does not slosh; (iii) The symmetry of local natures which suggests that the a woodpecker pecking on a tree and a football player being hit on the field are equivalent in a meaningful way; (iv) The ‘mimicry argument’ which suggests that the collar successfully facilitated the transposition of the woodpecker physiology into the human. This is, undeniably, a very shaky scaffold. While Nelson (2013, 2018) describes scientists who operate at extreme caution at height, they never come close to a site this precarious. This difference seems to reaffirm a distinction between Nelson’s mice, models primarily intended to scaffold further laboratory work, and the woodpeckers, intended here to ungird the sale of a sporting good. As an epistemological foundation, the woodpecker may provide little security but, culturally, it continues to compel action. The makers of the Q-Collar have, after all, already taken the technology to market.

Given both the potentially shaky epistemological grounding of the scaffold, the ethically charged nature of brain injury in football, and, in the broader context of CTE, the frequent accusations of conflict of interest, it in unsurprising that, first, there have been consistent and vigorous attempts to pull down the scaffold supporting the Q-Collar and, second, woodpeckers have been central to these attempts. James Smoliga, author of several critiques of the Q-Collar (e.g. Smoliga and Zavorsky, 2017a, 2017b), specifically addresses the issue of woodpeckers in an article with Lizhen Wang, who has written extensively on the biomechanics of woodpeckers (Smoliga and Wang, 2019). Published in the high-impact British Journal of Sports Medicine, the short article is a withering attack on ‘the woodpecker model of traumatic brain injury’ (Smoliga, 2018). Smoliga and Wang note that, and as discussed above, woodpeckers have multiple adaptations to protect their brains; woodpecker brains are quite different to human brains; and that the biomechanics of a woodpecker peck are quite unlike the rotational hits experienced on a sports field. The authors here echo Friese and Clarke, who note, drawing on work by Star (1983) that ‘social practices of transposition include “simplification work”’ (Friese and Clarke, 2012: 37) by suggesting that the simplification work behind the Q-Collar elides significant interspecies difference.

Perhaps most damningly, the authors suggest that there is no evidence that ‘woodpeckers contract their omohyoid muscle to occlude the jugular vein during pecking’ (Smoliga and Wang, 2019: 1262), potentially undercutting a biomimetic rationale of the Q-Collar. Writing with Zavorsky, Smoliga largely couches his criticism in terms of disciplinary difference (Smoliga and Zavorsky, 2017a: 756) but with Wang they are more direct, stating that the woodpecker model of TBI was ‘proposed by those without a history of woodpecker research, but with a financial interest’ (Smoliga and Wang, 2019: 1262). By foregrounding the woodpecker in these critiques, there is again an apparent recognition that the woodpecker is a ‘persuasive object’ (Roosth, 2017: 175) at the centre of the ethico-epistemic scaffold of the Q-Collar. If the ‘prescriptive character’ of the woodpecker were ‘undone’ then the whole scaffold may fall (Paxson and Helmreich, 2014: 180).

One striking criticism of the Q-Collar and related biomimetic endeavours is that while the assumption has been that woodpeckers don’t suffer neuropathological damage as a result of their activity, we don’t actually know whether this is the case. It is assumed that woodpeckers don’t get headaches but who has asked? To this end, Farah et al. (2018) studied the brains of a variety of woodpeckers procured from museum collections and found that ‘pecking may induce the accumulation of tau in the woodpecker brain’ (Farah et al., 2018: 1). The authors state that while neuroanatomical differences prevent a direct comparison, the ‘anatomic locations and staining patterns of the lesions identified in the brains of woodpeckers share some similarities to human CTE’ (Farah et al., 2018: 9). Unlike other attempts to shake the scaffold which are premised upon a prising reopen of the human-woodpecker divide, Farah and colleagues continue to envisage the lives of humans and woodpeckers as entangled. The interspecies divide, however, is crossed not by making the human more woodpecker, but by making the woodpecker more human. The woodpecker may not, it seems, be quite as home on the football field as we would imagine.