1. Introduction
Rowing is a whole-body exercise that is practiced in the modern world as a leisurely activity and a sport. With the establishment in 1892 of the World Rowing Federation (
Fédération Internationale des Sociétés d’Aviron (FISA)), the world governing body of the sport of rowing, rowing as a sport gained more uniformity and regulations to enhance its universality. In fact, World Rowing, through its rule book [
1], now sets the rules and regulations for the practice of rowing at international level for its on-water (coastal and flat-water) regattas and for indoor rowing (practiced on rowing ergometers that emulate the rowing action). As a result, with the exception of the historical regattas rowed on traditional local boats, the sport is normally practiced on highly standardized sliding-seat racing boats, or shells, which are regulated in terms of dimensions and weight. On these boats, the rower has her/his feet anchored on a fixed foot rest, and sits on a sliding seat facing the rear of the boat. This seat slides backwards and forwards, thus allowing the rower to utilize leg strength as optimally as possible.
On water, rowers can either row holding one oar with both hands (sweep rowing) or row holding a pair of oars, one in each hand (sculling). From the perspective of the hand, the rowing action involves constant “gripping” of the oar (with one or two hands), “pulling” actions, and a “rotation” (feathering) of the oar with every stroke during the drive phase, as well as a less demanding “pushing” and rotation during the recovery phase of the stroke, as described in
Figure 1.
The “stroke” on a standard rowing ergometer is simpler in form as the rotational feathering action is not required, i.e., it only involves “gripping” and “pulling” in the drive phase.
Typical oars used for sculling are around 284 cm–290 cm in length, whilst oars used for sweep rowing are typically longer,
circa 370 cm–376 cm in length. Oars are now typically all made from composite materials, which provide excellent weight-to-strength ratio and permit mass production, with the more common shape of the “blade” being the hatchet/cleaver blade style, first introduced in 1992, which is shown in
Figure 2a. The oars used in fixed-seat boats, mainly seen in traditional events with a historical context, such as the Maltese Traditional Regattas and in the Cornish County Championships (UK), are typically heavier (i.e., more difficult to handle and feather), designed in a more traditional manner, and made of wood as shown in
Figure 2. Note that in such traditional rowing, the use of a “reverse grip” for holding the oar is not uncommon (see
Figure 1c, to be compared with the sweep “standard grip” in
Figure 1b).
In the on-water World Rowing races, the standard rowing distance is 2000 m, typically lasting five and a half to eight minutes. Shorter distances of 1000 m are also not uncommon, particularly for master athletes. Coastal rowing races are normally either “endurance races”, which are much longer, with typical events being four to ten kilometers long, or “beach sprints”, which are much shorter races and start and finish from a beach. It is well known that the standard 2000 m race is “one of the most physically demanding efforts in the world of sport”, which “is not only physically demanding, but mentally exhausting as well” [
2]. Rowing is therefore not an easy sport to practice, and rowers are known to endure “unthinkable amounts of pain” [
3] and still keep rowing.
In 2020, the International Association for the Study of Pain (IASP) redefined pain as “An unpleasant sensory and emotional experience associated with, or resembling that associated with, actual or potential tissue damage” [
4]. Pain indicates, by giving signals, when harm is being done to bodily systems, so that a response stops further damage. Even though pain is a protective mechanism, all through evolution survival depended on tolerating painful stimuli, and in most sports, pain is inevitable. To obtain desirable results, most athletes have learnt to either tolerate pain or developed strategies to counteract it. Practicing sports activities, especially at a high level, induces pain [
5], and having the skills to tolerate or overcome this pain leads to success or failure in sports [
6]. Pain during exercise also induces fatigue, which, according to Gandevia [
7], is a “reduction in maximal voluntary muscle force. It may arise not only because of peripheral changes at the level of the muscle, but also because the central nervous system fails to drive the motor neurons adequately”. When dealing with pain, research suggests that athletes tend to use “acceptance” as a form of cognitive strategy [
8,
9].
Pioneering work published in 2003 by Ord and Gijsbers [
10] looked in detail at pain thresholds and tolerances of competitive rowers and their use of spontaneous self-generated pain-coping strategies. A more recent study by Cohen et al. (2009) [
11] adopted a similar protocol as that described by Ord and Gijsbers [
10] in their study about pain tolerance and thresholds of rowers, to evaluate pain thresholds for individual and group rowing. The authors postulated that when rowers trained as a group, their pain threshold was more elevated than when rowing individually due to an elevated “opioidergic effect”, similar to a runners’ high, induced by a sense of bonding when training with trusted team members. Such synchronized activity when working as a group, as demonstrated when rowing together, releases endorphins, which anecdotally might be called “a feel-good factor”, and this has the effect of increasing the pain thresholds when rowing. In agreement, Davis et al. (2015) [
12], argue that a sense of goodness, which might also be referred to as a “flow” state, is achieved when athletes train together due to the release of endorphins secreted when the group is working together, synchronized and bonded as one entity. Such a state leads to higher thresholds when measured after training.
Although prominence is normally given to lower-back and knee pain induced from rowing, injuries from rowing are not limited to musculoskeletal issues. In particular, during rowing races and/or training, athletes require high levels of both strength and aerobic power [
13,
14]. Typical maximal anaerobic power scores have been estimated at 900–1100 Watt (W) for heavyweight men and 650–800 W for lightweight men [
15]. In rowing races, athletes tend to adopt a positive race profile [
16,
17,
18,
19], which could be attributed to the athletes’ initial powerful phase. In fact, according to Steinacker (1993), forces of 1000–1500 Newton (N) are typically needed in the start of the race, 600–800 N in the start phase, 500–700 N during the race, and 600–700 N for the finish [
20]. Thus, the practice of rowing, which typically involves hundreds of strokes in a very short time where rowers grip and move the oars with such magnitudes of power, inevitably results in the hands of the rowers being subjected to strong tensile and shear forces, as well as friction, of a very high magnitude. This repeated friction between hands and oars exposes the anterior part of the palms and fingers to stressful shear forces, which may cause separation of skin layers and the development of friction blisters. [
21,
22,
23,
24,
25,
26]. “Friction blisters” (in this paper, referred to simply as “blisters”) are the result of excessive frictional trauma to areas of the skin [
27]. Practitioners who work in the sports of rowing know too well that rowers typically suffer from hand blisters, and, as well stated by Karlson (2000), “most rowers merely tolerate blisters as a necessary evil that will resolve as the skin adapts” [
21]. Mokha et al. [
26], in their work “Dermatoses in Rowers”, describe blisters as “painful vesicles and bullae on anterior surfaces of the palm and fingers”. The authors attribute these blisters mainly to the friction between hand and oar during feathering. They also state that (in sweep rowing) the hand closest to the rigger develops blisters on the palm, while the other hand, which grips the oar in a hook-like manner, develops blisters on the fingers. The authors also suggest that the tendency to develop multiple blisters can impact on hand placement on the oar due to the pain. The treatment known as “paring” by draining while leaving the roof of the blister untouched as well as taping or bandaging during rowing to avoid irritating them further is well known and described by various authors [
22,
26,
28]. Additionally, switching between different oar handle textures or types should be avoided.
The stratum corneum, the outer horny layer of the skin, can become thickened or callused, also termed “hyperkeratosis” (this paper, referred to simply as “callus”). Whilst being a protective mechanism to shield underlying structures from harmful repetitive stress, as the hyperkeratosis thickens, it can become a source of pain in itself. In other words, over time, repeated skin distress leads to the formation of protective hard skin calluses. [
22] Mokha et al. [
26] describe the rowing-induced calluses as yellowish “hypertrophic and thickened skin”, which serves to provide relief from excessive friction. This is hence an adaptation that rowers normally desire [
22]. Thus, it is not usual for rowers to seek treatment for calluses, though rowers typically trim or file them if the calluses become excessive [
22,
28].
Blisters and calluses in sports are not unique to rowers. Blisters are reported in various sporting events, for example, marathon running, with an incidence of up to 25% in athletes’ feet [
29]. A large national study of sport- and physical exercise-related injuries in the United Kingdom reported an occurrence of 2.2% for “tenderness, swelling, blisters” out of the 1429 respondents that reported being injured in any way. [
30]. No detail on the particular sport practiced in these cases was given. More specifically on hand skin injuries, a study by Smith and Krabak (2002) describes how 19.5% of participants of the 1998 Tug of War world championships reported “Abrasion/burn/blister” injuries. [
31] The authors commented on the similarity between Tug of War and sweep rowing when it came to injuries and also reported an observation that blisters appear to be “quite common”. Blister occurrence was also reported on in the sport of fencing, where 48%–65% of treatments needed during competitions are attributed to blistering [
32,
33,
34], as well as in the related yet distinct sports of canoeing and kayaking. A recent study by Feher reported that a quarter of participants in canoeing marathons get blisters [
35]. Dragon boating (an activity that is more similar to kayaking than to rowing) seems to be more inducive to hand blisters, with as many as 78.9% of dragon boaters in a study reporting blisters. [
36]
Despite the fact that rowing causes blisters and calluses on the palm of the hand and fingers, it is common knowledge that, in general, training generally continues, possibly exacerbating the issue and increasing the possibility of infection [
22]. This problem may be further aggravated when the rowers decline the use of gloves, which are perceived as hindering the real feel of the oar [
21]. Notwithstanding such interesting observations, and the availability of various online publications aimed at rowers that discuss rowing blisters and suggest ways to care for them [
37,
38,
39,
40], no study seems to have looked into this issue in a more quantitative manner. In fact, to our knowledge, although the prevalence of blisters and calluses is generally regarded as high in active participants, there is no reported quantitative research to systematically evaluate the prevalence of blisters and calluses, where they occur, the manner in which rowers react to them, and the impact these blisters and calluses may have on rowers (e.g., on their performance in the sport and/or on other aspects of their life).
In view of this, the present study is intended to form initial evaluations about trends, opinions, and frequencies obtained quantitatively about blisters and calluses of on-water rowers. The research questions in this study are envisioned to descriptively investigate how these dermatological conditions affect water rowers’ hands, mainly their fingers and palms, inquire about the frequency of their prevalence, causes, and care. Another intent of this study is to inquire about the rowers’ perception of pain while rowing on water and how these dermatological conditions affect the rowers’ life and identity.
4. Discussion
This study has drawn some very valid and novel conclusions about the behavior of rowers. First and foremost, it confirmed quantitatively most that was known qualitatively, i.e., that, as stated in a previous publication by [
21], the “hands of rowers are highly susceptible to blisters” and that “most rowers merely tolerate blisters as a necessary evil that will resolve as the skin adapts.” [
21]. In fact, most of the participants have admitted that they are prone to blisters and calluses, with only 2.07% stating that they never had blisters and 1.38% that they never had calluses. What is the most remarkable, and previously undocumented, is the magnitude of the problem, with almost 81.38% acknowledging suffering from blisters and calluses on different degrees of regularity. Such a high prevalence in hand blisters and calluses puts rowing as one of the sports with the higher incidences of such skin conditions [
31,
32,
33,
34,
35].
Also remarkable is the rowers’ attitude. The rowers are willing to withstand the pain (confirmed through this study), even despite knowing there is the possible exposure to infection, much highlighted by sports medical practitioners [
23], even ones in the field of rowing, with Karlson (2000) [
21] stating that “A few may get secondary infections, which often require oral antibiotic treatment. More serious infection is rare” [
21] with Rumball et al. (2005) [
22] stating that “blisters … may lead to infection (‘sausage fingers’) if not cared for properly in the acute stages.” [
22]. Most participants admitted that they would either do nothing (28.57%) to cure blisters or self-medicate (44.44% draining; 43.65% taping), as suggested in various online publications [
37,
38,
39,
40]. Here, it must be said that since our research found such a low incidence of blisters being infected, it could well be that most rowers who participated in the study may be oblivious to the fact that infection may be a real threat. In fact, it may be extrapolated from the data collated in this study that, given the low incidence of such infections, most rowers will never experience infected blisters either on themselves or on a fellow member of their crew. It must, however, be said that the scientific rowing literature reported that there is a risk, albeit low, that there could be serious consequences if blisters get infected, and this should not be overlooked. A respondent made this very clear though a very poignant comment “My son was hospitalized for a rowing related hand infection. I.V. Meds for days. He rowed at a national level.”
This research shows that this population not only accepts blisters and calluses, but also accepts the fact that they are part of the rowing lexicon. Nearly all of the participants agree that blisters and calluses are inevitable (93.10%), and almost half (47.58%) of the respondents agree that blisters and calluses are something to be proud of, as they demonstrate that they form part of the rowing culture. However, less than half of the rowers in this study agree that blisters are a sign of hard work. Rowers have admitted that the formation of blisters may be attributed to “gripping too much” (35.71%), when they change the oars or row in a different position (14.29%), or “unconditioned hands” (50.00%), for example, at the start of the season. Past scholarly studies in fact espouse the formation of blisters with how the oar is handled [
21]. Future research can also correlate the type of oars used and the type of handling with blister formation.
Another unique finding from this study is that the discomfort or pain from blisters and calluses does not affect rowing performance and task completion, with 74.10% admitting that blisters and calluses have no effect or a minor effect on rowing itself, with the majority of rowers (93.10%) admitting that blisters and calluses are inevitable and part and parcel of a rower’s life. Most participants have also agreed that they do not think that blisters or calluses have an effect on the quality of their personal life (76.98%), their work (81.29%), leisurely activities (80.60%), relationship with friends (92.80%), or the image of themselves (92.80%), even if 39.40% admit that blisters and calluses are “ugly”.
This research has exposed the finding that the majority of the rowers (76.26%), who are also active competitors, claimed that having both blisters and calluses would not stop them from rowing, indicating that they would still row even when they perceive pain or discomfort, as they themselves admitted to feeling, albeit at different levels. This finding is similar to the interesting finding that emerged from research carried out by Hoffmann and Krouse [
45], who asked participants whether they would stop practicing the sport (running) if it proved to be detrimental to their health. Of the athletes, 74.1% admitted that they would not stop their activity, similar to the finding in this study. The fact that the rowers do not stop rowing, despite having blisters and calluses, indicates that they have learnt to cope well with this stressor. Coping in sports refers to mechanisms that athletes adopt to manage stressors or stressful situations to ameliorate their relationship with the said stressors while practicing their sport. Lazarus and Folkman [
46] define coping “as a constantly changing cognitive, behavioral, and affective process individuals use to manage stressors that are appraised as taxing or exceeding their resources”. These mechanisms, which might be cognitive in nature, can also augment the pain tolerance of the athletes. Roebuck et al. [
47] argue that an elevated pain tolerance in the athletic population is achieved by the use of cognitive coping mechanisms that are spontaneous and involuntary. In their study, Ord and Gijsbers [
10] found that the elite rowers could tolerate pain induced by sphygmomanometer pressure for a much longer time period than the controls could. These rowers attributed their higher tolerance to using multiple high-level cognitive methods to control pain sensations. A salient theme that emerged from this study is that almost all of the participating rowers (76.26%) admitted that they would keep rowing even with these dermatological ailments, because they have learnt to accept them. Rowers are indeed aware of the fact that blisters and calluses are going to be present throughout the season and used acceptance as a mechanism to deal with the pain and discomfort. Acknowledging and accepting a stressor is a cognitive coping strategy [
6] used by sports practitioners mostly when they cope directly with the stressor in order to deal with it. The participants did not turn away from the stressor (pain) or use methods to avoid it (most do not even take measures against the pain and likely infection caused by blisters) but rather affronted the stressor and accepted its presence. Carver et al. [
8] argue that acceptance occurs during secondary appraisal and is a functional coping response in which the stressor is something that is “accommodated to” since it cannot be changed.
Cognitive strategies to manage pain and enhance tolerance during exercise were also described in a study carried out by Simpson et al. [
48], where athletes described that they employed mental skills to manage adversities such as fatigue and pain to maintain a good performance. Tezars et al. [
49] in fact also discuss that there is a positive relationship between pain tolerance and acceptance. Once the discomfort is accepted, discomfort can be tolerated better. Carver et al. [
8] believe that acceptance is a strategy used when there is no other alternative and by engaging in such a strategy, the rowers are in fact dealing with the stressor to ameliorate the situation. Costa and Pinto-Gouveia [
50] argue that acceptance of the stressor, in this case pain and discomfort originating mostly from blisters, makes sense since it is useless fighting the inevitable when energetic resources can be spent in a more fruitful manner.
Past studies have shown that athletes who adopted this cognitive method could then focus inward on themselves to complete the task without any form of distraction. Most of the rowers (76.3%) in this study were similar to the elite runners described by Morgan and Pollok (1984) [
51] who used associative strategies and read corporeal signals without ignoring what their body was telling them. The rowers admitted that they accepted the blisters, calluses, and related pain, thus converging their cognitions inwards and forming a task-relevant (internal) association as described by Stevinson [
52]. Other past literature [
10] has shown that the pain tolerances of rowers are quite elevated when compared to controls, although there was no distinction between pain thresholds [
53,
54]. (The greatest amount of pain an individual demonstrates willingness to assent to is called pain tolerance [
55], while pain threshold is defined as the minimum intensity of a stimulus that is perceived to be painful [
53].) This concurs with our finding that fun and competitive rowers rate pain due to blisters at approximately the same levels, indicating that they have the same thresholds. In the case of this study however, almost all the athletes admitted that they would continue rowing despite the blister pain, so no significant pain tolerance distinction between the groups could be exposed. Future research might try to analyze this further, by adopting different protocols to assess pain tolerance between the groups.
Having a solid control of situations that cause stress indicates a good level of mental toughness. There are various definitions of mental toughness, one of them being the ability to make use of coping strategies effectively [
56]. Extant research has been shown to bind the construct of mental toughness with effective coping [
57,
58,
59], which then leads to successful task completion despite having to deal with stressors like pain. In the case of the participants in this study, mental toughness was demonstrated by the willingness of the rowers to continue rowing despite the formation of blisters and calluses and also by adopting a strong cognitive strategy to enable them to complete their task.
The fact that all groups admitted that they would carry rowing on despite the pain from blisters reveals that most (76.3%) of the rowers, as a population, demonstrated that they have a superior pain tolerance. Tesarz et al. [
49] revealed that an elevated pain tolerance is also related to a long-standing training regime that may alter pain perception. In reality, most (51.7%) of the participant rowers have been rowing for more than 10 years and 40.7% have been rowing between 3 and 10 years, and this longevity in the sport might be a contributing factor that affected their tolerances. It must however also be said that the study also suggests that painful blisters typically occur at the start of the rowing season, which typically is characterized by long steady-state rows, which are likely to be more tolerable by rowers with blistered hands when compared to high-intensity power-burst workouts, such as interval training or “starts”. Additionally, it is more than likely that most members of the crew on the same shell would be afflicted by blisters of some degree, i.e., no individual rower would feel under the pressure of letting down fellow crew members.
Another significant finding in the case of rowers in this study was the admission of rowers that their willingness to continue rowing despite the blisters and calluses was also related to their affinity towards the sport. Results show that 45.3% of the participant rowers admitted that they would not stop as they “simply love the sport”. Elite runners described by Morgan and Pollok [
51] showed a similar trait when they admitted that they enjoyed the feel-good factor the sport rewarded them with. Future research may be aimed at finding the reasons why participants have this passion for rowing.
Before concluding, it is important to mention some issues that merit further study. For example, in view of the high prevalence of blisters and calluses encountered by these athletes, further research is required in order to address the etiology of these lesions. Such research should also look into ergonomics and equipment design. Furthermore, it is not clear how the majority of the respondents of the present study say that blisters do not affect their rowing, when extant research has shown that blisters might be the deciding factor of an athletic competition if it results in reduced performance or incapacity for a key person at a critical time [
23], and can also cause intense pain [
24]. Indeed, 10.34% strongly agree and 45.52% of the participants agree that they perceive some sort of pain or discomfort from blisters acquired during rowing, of which 5.52% perceive this pain as extremely painful. Future research can reveal the reasons why very few rowers deem rowing with blisters and calluses as being extremely painful and why a majority of amateur rowers find it not painful at all.
Another aspect that deserves to be looked into more closely is the very interesting finding that most of the participants who deemed blisters as not painful (level 1) were noncompetitive athletes (29.17%, as opposed to Club level—7.55% and National/International level—10.20%), while most club/regional and national/international athletes deemed blisters as only being reasonably painful (3 on a scale of 1 to 5). This might be due to different training regimes and expectations from athletes of different levels. In fact, our results show that national and international rowers train at a much higher intensity than the fun rowers and club/regional-level athletes do since they participate in high-level competitions and may need to give maximum effort, which might not be the case when rowing for fun and health. For example, when the training intensity reaches level 4 on a scale of 1 to 5, only 35.7% of the Category I rowers admitted to training at that level, in contrast to 67.2% of club/regional-level (Category II) rowers and 64.3% of national/international (Category III) rowers. A limitation of this finding is that the athletes were not assessed on the same parameters to rate pain, such as using the same protocol to assess the pain induced by rowing in the same conditions.
Finally, it is important to highlight some of the strengths and limitations of this work. An important limitation is that the study was always conducted remotely and the respondents could not interact with the researchers carrying out the study. This could lead to some inaccuracies stemming from misunderstanding questions. Moreover, the method used made it impossible to decipher whether the respondents were answering questions truthfully. On a more positive note, this work has finally addressed the issue of hand blisters and calluses in a quantitative manner, and was able to confirm various opinions put forward by others. It also brings to the limelight what rowers really think of their blisters and calluses and how they deal (or rather do not deal) with them. Such study, to our knowledge, had never been carried out before. The present study could also form the basis for further, more focused studies, such as whether the forced extended breaks from rowing caused by COVID-19 lockdowns could have aggravated or alleviated rowing injuries, including skin conditions. Further studies could also look into why so few rowers seem to suffer from infections when they have blisters on their hands. It would also be useful to look into special populations, such as junior athletes, para athletes, as well athletes with specific medical conditions such as diabetes. In addition, the participants in the present study tended to row in more than one position, making it futile to attempt to relate location of blisters and calluses to the manner how the oars are held. As a result, in a future study, it would be useful to focus on rowers who only practice sweep rowing, or who only scull. It would also be interesting to examine athletes who exclusively practice fixed-seat rowing so as to assess whether they are more prone to blisters and calluses. Moreover, the future study could ask more specific questions, such as how the rowers work-around blisters to be able to continue training, or how prepared they would be to reduce the intensity of rowing training if they, or fellow crew members, are afflicted by painful blisters.
5. Conclusions
In conclusion, this study has quantified the prevalence of blisters in rowers, which seems to be independent of the extent and intensity of rowing, and demonstrates that although there may be pain associated with them, for most rowers, the passion for rowing is stronger than the pain itself. More specifically, it was estimated that around 69% of rowers are regularly sporting calluses on their hands, which they generally classify as not painful, whilst the prevalence of blisters is less pronounced. It was shown that the more common locations for these blisters and calluses are the lower parts of fingers and upper part of the palm.
This work has found that the participants claim that blisters and calluses are derived from the rowing movements, and their etiology is attributed either to unconditioned hands at the start of the season or due to a change in our position. All rowing categories show the same prevalence trend irrespective of which intensity they train at.
This study also suggests that rowers tend to not let these skin injuries impact on their training or lives, and they do not stop them from rowing. Claiming that these conditions are inevitable, the rowers have adopted a coping strategy of acceptance. Apart from this coping method, the rowers also feel pride in these injuries, which also make them part of this hardy population. A practice of simple acceptance and some pride in these injuries is common. Essentially, rowers are mentally tough athletes who show that they are willing to practice their sport even at the highest level despite having blisters and calluses by adopting a cognitive mechanism to maintain control of the discomfort and pain.
Finally, it was also found that the incidence of infections in blisters may not be as high as indirectly suggested in the literature, with the consequence that one may estimate that few rowers would ever encounter any case of serious infection, either on themselves or in a fellow member of their crew, with the result that they may not fully appreciate the seriousness that such an infection, if it indeed occurs, could bring with it.