86 SAJSM vol 19 No. 3 2007 Introduction An unaccustomed bout of eccentrically biased exercise re- sults in trauma to muscle and/or connective tissue. It is now well established that if a similar bout is repeated within sev- eral days 22 to several months, 15 there is a significant reduc- tion in direct and indirect markers of muscle damage. 13 This response is referred to as the repeated bout effect and is believed to represent a positive training adaptation. 13 Several hypotheses have been proposed in an attempt to explain this phenomenon. McHugh 13 has classified these hypotheses as the neural, mechanical, and cellular adaptation. 13 One aspect of the cellular adaptation hypothesis that is gaining in acceptance is related to the initial acute inflammatory response after the first bout of eccentrics. 16 Although acute inflammation promotes healing, an undesirable ‘side-effect’ of this process involves the release of catabolic substances that inadvertently degrade surrounding healthy tissue. Pizza and colleagues 18,19 have suggested that the repeated bout effect may be related to origiNAl reSeArch ArTicle changes in neutrophil count, creatine kinase and muscle soreness after repeated bouts of downhill running Abstract Objective. A primary objective was to examine circulating neutrophil count after repeated bouts of downhill running. An additional aim was to determine creatine kinase (CK) levels during the initial 12 hours, after repeated DHRs. Design. Eleven healthy, untrained Caucasian males per- formed 2 x 60 min bouts of DHR (-13.5%), spaced 14 days apart, at a speed equal to 75% VO2max on a level grade. Blood was collected before, after, and every hour for 12 hours, and every 24 hours for 6 days. Absolute neutrophil count, CK, and delayed-onset muscle soreness (DOMS) were assessed. Results were analysed using repeated measures ANOVA (p<0.05) with appropriate post hoc tests. Results. There were no significant differences in neutro- phil count (p=0.24) during the 12-h period following run 1 (mean±se, 6.45±0.29 10 -9 .l -1 ) versus run 2 (5.96±0.09 10 -9 .l -1 ), or during the 24-h periods for run 1 (3.48±0.09 10 -9 .l -1 ) or run 2 (3.47±0.09 10 -9 .l -1 ). During the initial 12-h CORRespOnDenCe: Lucille L Smith Department of Sport, Rehabilitation and Dental Sciences Tshwane University of Technology South Africa E-mail: smithll@tut.ac.za Tel : 012-382-5921 Cell: 082-561-8932 lucille l Smith (PhD)1 Stuart J Semple (D Tech)1 Andrew J McKune (D Tech)1 Nevel Neveling (Biokinetics/M Tech)1 Miguel caldeira (Biokinetics/B Tech)1 Jean-Marie Swanepoel (B Tech)1 lebogang Tsomele (B Tech)1 Melissa Naidoo (BSc hon)1 emmanuel Sibanda (M Tech)2 1 Department of Sport, Rehabilitation and Dental Sciences, Tshwane University of Technology, Pretoria 2 Department of Statistical Services, Tshwane University of Technology, Pretoria period, there was a significant interaction effect (p=0.0001) for CK with differences between bouts seen between 3 - 12 h; differences remained evident at 24 h and at 96 - 144 h. In all muscle groups, DOMS was significantly lower after run 2 compared with run 1. Conclusion. The lack of significance in neutrophils, as well as the early onset of difference in CK between run 1 and run 2 were attributed to the type of eccentric protocol used. It was proposed that future studies be more cognisant of whether the eccentric mode is predominantly low-intensity long-duration or high-intensity short-duration. PG86-93.indd 86 10/3/07 3:27:23 PM SAJSM vol 19 No. 3 2007 87 an attenuated inflammatory response after the second bout. This suggestion has been supported by the observation that there is a significantly reduced number of circulating neutrophils after the second bout of eccentrics, compared with the first. Since neutrophils are typically the first white blood cells to enter damaged tissue and are instrumental in initiating an acute inflammatory response they reasoned that reduced circulating numbers of neutrophils after bout two, would result in reduced infiltration into damaged tissue and a reduction in subsequent inflammatory events. In contrast to the findings of reduced neutrophilia after bout 2 ,18,19 a previous study 21 found no significant differences in neutrophil count when a second bout of eccentrically biased exercise was performed a few weeks after the initial bout. However, a primary difference between the two studies was the exercise protocol. Pizza et al. 18,19 used high- intensity, low-volume resistance-like eccentric contractions of the elbow flexors, while the aforementioned study 21 used repeated bouts of downhill running, which incorporated low- intensity high-volume aerobic-like eccentric contractions. An alternate reason for the lack of consensus between these studies could have been that in the previous downhill running study, 21 the intensity, the steepness of the gradient and the duration of the running bouts were not sufficiently strenuous. Therefore, a primary purpose of the present study was to re- examine circulating white cell counts, specifically neutrophils and also monocytes after two bouts of downhill running, using a higher intensity and longer duration. Serum creatine kinase (CK) has frequently been used as an indirect marker of muscle damage. With regard to repeated bouts of eccentrics, CK has consistently been shown to be significantly lower after the second bout of eccentrics. 3,8,14,18,21 However, in previous downhill running studies 3,5,21 CK was only measured at 24-h intervals; whether differences in serum CK are evident at an earlier time point after downhill running has not been investigated. Thus, an additional purpose of this study was to assess total circulating CK at 3-h intervals during the initial 12 h, as well as at 24-h intervals for 6 d, following both downhill runs. Methods subject selection Eleven healthy, active but untrained Caucasian males were recruited for the study; ‘untrained’ was defined as not hav- ing engaged in regular sport or physical activity for at least 6 months. Selection criteria for subjects included the follow- ing: age between 18 and 30 years; no history of leg injury or any other medical condition that would be exacerbated by two bouts of downhill running; no regular usage of any anti- inflammatory medication. Initial screening The individuals selected to participate were scheduled for screening in the Exercise Testing Laboratory (ETL). During the first visit they were required to read and sign an informed consent previously approved by the University Ethics Com- mittee and in accord with guidelines established by the Amer- ican College of Sports Medicine. Height and body mass were assessed. Body composition was assessed using a 7-site skinfold caliper (Harpenden, British Instruments, London). The sites were: chest, midaxillary, triceps, subscapular, ab- domen, supra-iliac, thigh). The equation used was: body den- sity = 1.112 - 0.00043499 (sum of 7 skinfolds) + 0.00000055 (sum of 7 skinfolds) 2 – 0.00028826 (age). 1 Assessment of VO2max and determination of individual running speeds Subjects were instructed to eat a light meal 3 hours prior to the VO2max testing. To determine VO2max, subjects were re- quired to walk/run on a treadmill using the Bruce protocol. 1 The test was performed on a Quinton 90 treadmill (Quinton Instrument Co. Seattle, Washington). Continuous respiratory measurements were recorded by means of the MedGraph- ics CardiO2 combined VO2 /ECG exercise system (Medical Graphics Corporation Chicago, Illinois). Throughout the test, heart rate was recorded at the end of each minute using a Polar™ Heart Rate Monitor (Accurex 2, Polar Electro, Fin- land). Ratings of perceived exertion (RPE) were recorded at the end of each stage (every 3 minutes), as well as when subjects reached volitional exhaustion; the 15-point Category Scale was used. 1 The test was accepted as VO2max if two of the following criteria were attained: RER > 1.1 and/or; RPE > than 19 on the 15-point RPE Scale, and/or maximum heart rate (HR) within ± 20 beats of age predicted HRmax. After the test, VO2max (ml.kg -1 .min -1 ) values were converted into metabolic equivalents (METS). Seventy-five per cent of the peak MET capacity was then calculated. Metabolic equations were used to determine the speed on a level grade that would elicit this MET capacity. 1 This treadmill speed was the designated speed for each subject for both downhill runs. eccentrically biased downhill run During the 72 h prior to the downhill run, subjects were in- structed to ingest a normal mixed diet, to be well hydrated, and to refrain from any strenuous exercise. Each subject performed two identical bouts of downhill running spaced 14 days apart (run 1 and run 2). On both days subjects ran between 5:00 am and 11:00 am and repeated runs were at approximately the same time for each subject. Subjects were instructed to fast overnight, but were encouraged to drink ad libitum, to ensure euhydration. At the start of both runs, sub- jects warmed up for 5 minutes by running on a level grade at the pre-determined speed. The treadmill was then lowered to –13.5% and subjects ran for 60 min. Heart rate was re- corded at the end of each minute (Polar™ Heart Rate Moni- tor, Accurex 2, Finland). Blood sampling On arriving in the laboratory, before run 1 and run 2, subjects were required to sit quietly for 10 min. A qualified phlebot- omist then inserted a venous catheter (22 gauge, 2.2 cm), PG86-93.indd 87 10/3/07 3:27:23 PM 88 SAJSM vol 19 No. 3 2007 which was kept patent for the following 12 h, using a saline solution. Blood was drawn at the following times: pre-ex- ercise, immediately after (post), 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 and 12 h after (14 samples x 15 ml per sample = 210 ml blood over approximately 14 h). In addition, subjects were required to return to the ETL 24, 48, 72, 96, 120 and 144 h later, for additional blood draws (6 days x 15 ml = 90 ml). At these times, a standard venipuncture was performed using an antecubital vein. Plasma (5 ml whole blood) was collected in EDTA tubes and used for assessment of total and differential white cell count and for assessment of CK. Serum (10 ml whole blood) was collected in serum separator tubes, allowed to stand at room temperature for 30 min and then spun down for 10 min at 2 000 x g. Aliquots were frozen at –70°C in 0.5ml eppendorf tubes. Subjects remained in the ETL for 12 h after run 1 and run 2. They were provided with food and fluid and encouraged to eat, and especially to drink, ad libitum. Total and differential white cell count Values were assessed before and immediately after exer- cise, and then every hour for 12 h, as well as 24 - 144 h. Total and differential white cell count were determined using a Cell-Dyn 3000 (Abott Laboratories, Mountain View, CA) and analysed by laser-based flow cytometry. All samples were analysed within 16 h of collection. Assessment of CK CK was assessed at the following times: before, immediately after, 3, 6, 9, 12, 24, 48, 72, 96, 120 and 144 h after exercise. Blood CK concentrations were determined using a Refletron blood analyser, which uses a colorometric assay procedure (Boehringer Mannheim GmbH, Germany). EDTA blood (32 µl) was pipetted onto a Refletron CK strip (Roche Di- agnostics, Indianapolis, IN). The strip was inserted into the Refletron analyser for 30 sec. Printed results were recorded. If values were > 1 500 IU/l the sample was diluted with equal parts distilled water; 32 µl of this mixture was then pipetted onto a strip and rerun immediately. Values of diluted blood were then doubled. Assessment of DOMs Subjective soreness ratings were assessed before exercise and at the following times after exercise: 6, 12, 24, 48, 72, 96, 120, and 144 h. Subjects were asked to gently palpate and move various muscle groups through a comfortable range of motion. They were then asked to rate each muscle group individually, by placing an ‘X’ along a visual analogue scale (VAS) of 10 cm. The verbal anchors on this scale were ‘1 = normal’ and ‘10 = very, very sore’. 19 The distance in cen- timeters from the beginning of the scale to their mark was measured and this represented the muscle soreness score for that particular muscle group. statistical analysis All dependent variables were analysed using a repeated measures ANOVA. Separate analyses were performed for the initial 12-h periods and for the 24-h periods with all val- ues being compared with pre-exercise levels. Significance was set at p<0.05. Where significant main effects or interac- tion effects were found, a post hoc Least Square Means was used. All values reported are means ± se. Results physical characteristics of subjects Physical characteristics of 11 subjects were: age (years) = 19.7±0.4; height (m) = 1.79±0.3; mass (kg) = 78.5±3.0; body fat (%) = 14.6±3.2; VO2max (ml.kg -1 .min -1 ) = 47.8±3.6. The main effects in this study were bout (run 1 versus run 2) and time (initial 12-h period and then 24-h intervals for 6 d). Any interaction effects represented differences be- tween bouts (run 1 versus run 2) at a specific time(s). Values reported are means ± se. White cell counts Neutrophil count (Tables I and II) For the initial 12-h period there was no significant bout (p=0.24) or interaction (p=0.4) effect. There was a signifi- cant time effect (p=0.0001). Neutrophils were significantly elevated over baseline (3.30±0.76, 10 -9 .l -1 ) at 2 h (7.74±0.76, 10 -9 .l -1 ), 3 h (7.39±0.76, 10 -9 .l -1 ) and 4 h (9.69±0.78, 10 -9 .l -1 ). For the 24-h comparisons there were no significant run (p=0.9), time (p=0.9), or interaction (p=0.6) effects. Monocyte count For the initial 12-h period there was no bout (p=0.06) or in- teraction (p=0.89) effect. However, there was a significant time effect (p=0.0001). From 4 h after exercise through 12 h, monocytes were significantly elevated over pre-exer- cise baseline levels (0.51±0.03, 10 -9 .l -1 ), with peak values seen at 6 h (0.89±0.03 10 -9 .l -1 ). For the 24-h comparisons there were no significant bout (p=0.12) time (p=0.62) or inter- action (p=0.93) effects. Creatine kinase (Fig. 1) For the initial 12-h period there was a significant interaction effect (p=0.0001). Post hoc testing revealed that values for run 1 were significantly higher than for run 2 at the following times: 3 h (557±48 v. 289±48 IU.l -1 ), 6 h (936±51 v. 402±48 IU. l -1 ), 9 h (1242±48 v. 514±48 IU.l -1 ) and 12 h (1243±58 v. 535±48 IU.l -1 ). There was also a significant bout effect (p=0.0001), with values for run 1 v. run 2 being 727±21 IU.l -1 v. 347±20 IU.l -1 , respectively. For the 24-h comparisons there was a significant interaction (p=0.0001) effect. Post hoc testing revealed significant differences between run 1 and run 2, respectively, at 24 h (827±49 v. 319±49 IU.l -1 ), 96 h (533±49 v. 132±49 IU.l-1), 120 h (499±49 v. 141±49 IU.l -1 ) and 144 h (404±49 PG86-93.indd 88 10/3/07 3:27:24 PM SAJSM vol 19 No. 3 2007 89 v. 153±49 IU.l -1 ). There was also a significant bout effect (p=0.0001). Values for run 1 (456±9 IU.l -1 ) were significantly higher than for run 2 (174±19 IU.l -1 ). It was interesting to note that CK peaked at 9 h and 12 h after run 1 and run 2. Delayed-onset nuscle soreness (DOMs) DOMS was reported in several different muscle groups which include the following: Upper back (Fig. 2A): There was a significant bout effect (p=0.0004), with run 1 being significantly higher (2.4±0.1) than run 2 (1.8±0.1). Peak soreness for upper back occurred at 24 h for both runs (4.5±0.4 v. 2.6±0.4). Lower back (Fig. 2B): There was a significant bout effect (p=0.0001), with run 1 (2.4±0.1) being significantly higher than run 2 (1.6±0.1). Peak soreness occurred at 24 h for run 1 (3.5±0.3) and run 2 (1.8±0.3). M. gluteus max (Fig. 2C): There was a significant bout effect (p=0.0001), with run 1 (2.7±0.1) being significantly higher than run 2 (1.8±0.1). Peak soreness occurred at 24 h for run 1 (3.8±0.4) and run 2 (3.1±0.4). Quadriceps (Fig. 3A): There was a significant bout (p=0.0001) effect with values for run 1 (3.1±0.1) being Table I. neutrophil and monocyte count before and after repeated bouts (run 1 and run 2) of downhill running neutrophil count (10 -9 .l -1 ) Monocyte count (10 -9 .l -1 ) Time (h) Run 1 Run 2 Run 1 Run 2 Before 3.209±1.073 3.400±1.073 0.500±0.033 0.509±0.033 After 4.418±1.073 4.856±1.073 0.463±0.033 0.491±0.033 1 6.909±1.073 6.368±1.073 0.518±0.033 0.509±0.033 2 7.957±1.073 7.526±1.073 0.645±0.033 0.663±0.033 3 7.636±1.073 7.139±1.073 0.654±0.033 0.636±0.033 4 7.405±1.130 6.624±1.073 0.731±0.035 0.727±0.033 5 7.265±1.072 6.109±1.073 0.808±0.033 0.800±0.033 6 6.979±1.130 5.809±1.073 0.931±0.035 0.845±0.033 7 6.773±1.073 5.527±1.073 0.860±0.033 0.854±0.033 8 6.702±1.130 5.245±1.073 0.841±0.035 0.782±0.033 9 6.627±1.073 5.082±1.073 0.809±0.033 0.727±0.033 10 6.396±1.129 4.927±1.073 0.733±0.035 0.709±0.033 11 6.182±1.130 4.791±1.073 0.778±0.035 0.718±0.033 12 5.809±1.072 4.682±1.073 0.718±0.033 0.672±0.033 Before After 3 6 9 12 24 48 72 96 120 144 Time (h) 0 200 400 600 800 1000 1200 1400 C re at in e K in as e (I U /L ) RUN1 RUN2  Fig. 1. Changes in blood levels of creatine kinase across time (before exercise through 144 h), for run 1 (circle) and run 2 (triangle). The cross symbol represents significant differences between bouts at specific times. Table II. neutrophil and monocyte count before and after repeated bouts (run 1 and run 2) of downhill running neutrophil count (10 -9 .l -1 ) Monocyte count (10 -9 .l -1 ) Time (h) Run 1 Run 2 Run1 Run 2 Before 3.209±0.224 3.400±0.224 0.500±0.027 0.509±0.272 24 3.818±0.224 3.282±0.224 0.500±0.027 0.445±0.027 48 3.418±0.224 3.456±0.237 0.463±0.027 0.435±0.029 72 3.309±0.224 3.636±0.237 0.473±0.027 0.465±0.029 96 3.436±0.224 3.354±0.224 0.482±0.027 0.454±0.027 120 3.658±0.237 3.518±0.224 0.464±0.029 0.464±0.027 144 3.497±0.224 3.639±0.224 0.484±0.027 0.453±0.027 PG86-93.indd 89 10/3/07 3:27:24 PM 90 SAJSM vol 19 No. 3 2007 significantly higher than for run 2 (1.6±0.1). There was also an interaction effect (p =0.0079), with run 1 being significantly higher than run 2 at 24 (5.0 v. 2.5) 48 (4.8 v. 2.2) and 72 h (4.3 v. 2.1). Peak soreness occurred at 24 h for both runs. Hamstrings (Fig. 3B): There was a significant bout effect (p=0.0001). With run 1 (2.4±0.1) being higher than run 2 (1.6±0.1). Peak soreness occurred at 48 h for run 1 (3.8±0.4) and at 24 h for run 2 (2.3±0.3). M. tibialis anterior (Fig. 3C): There was a significant bout effect (p=0.0001), with run 1 (2.3±0.1) being higher than run 2 (1.5±0.1). Peak soreness in this muscle group occurred at 72 h for run 1 (2.9±0.3) and at 48 h for run 2 (2.0±0.3). M. triceps surae (Fig. 3D): There was a significant bout effect (p=0.0001) with run 1 (3.3±0.2) significantly higher than run 2 (1.9±0.2). Peak soreness occurred at 72 h for run 1 (4.4±0.5) and at 24 h and 48 h for run 2 (2.7±0.5) Discussion A primary finding of this study was the confirmation of results from a previous study, 21 that there were no significant dif- ferences in neutrophil count when comparing an initial bout with a subsequent bout of downhill running. This is contrary to previous findings after repeated bouts of high-intensity eccentrics, 17,18 where significantly lower levels of circulating neutrophils were found after the second bout. Regarding CK, significant differences between bouts were seen at 3, 6, 9 12 and 24 h after both bouts, as well at 96, 120 and 144 h after exercise. We believe that this is the first study to report this disparity in CK so soon after bouts of downhill running. Concerning DOMS, after run 1, it was interesting to note that soreness peaked at different times in different muscle groups. Furthermore, peak soreness did not always occur at the same time points in the same muscle groups after run 1 and run 2. neutrophil and monocyte count Neutrophilia is an important aspect of acute inflammation and has been reported to occur after an initial bout of unac- customed eccentrics. 16 A critical aspect of neutrophilia is that the increased circulating count precedes the activation and migration of neutrophils into damaged tissue. 17 In addition, the subsequent presence of neutrophils in damaged tissue is an initiating event in the acute inflammatory response. 16 Pizza et al. 17,18 have proposed that the reduced neutrophilia as well as the reduced activation of these cells after a re- peated bout of eccentrics could, in part, be responsible for the repeated bout effect. They suggested that dampening of an initiating event could reduce the up-regulation of subse- quent associated events. If the above supposition is correct, a central question is why the disparity in results between various studies, which for the most part confirm a repeated bout effect? 17,18 A noticeable difference between previous studies conducted by Pizza et al. 17,18 and Smith et al., 21 as well as in the present study, is the mode of eccentrically biased exercise used to induce muscle trauma. Pizza et al. 17,18 had subjects perform two bouts of forced lengthening contractions of the forearm flexors of the non-dominant arm, separated by 3, 18 or 4 weeks; 17 it is proposed that this be regarded as high- intensity, low-repetitions resistance-like eccentrics. On the other hand, in the present study and in a previous study, 21 the mode of exercise involved downhill running; it is proposed that this be regarded as low intensity, high repetitions aerobic-like eccentrics. 11,12,21 Although much emphasis has been placed on differences in training adaptations associated with high-force resistance-like exercise, 14 versus low-force, high-repetitions, such as occurs in aerobic-like exercise, surprisingly, these differences have been virtually ignored in terms of exercise-induced muscle damage. During high-force eccentrics it is possible that the primary damage is within the muscle fibre per se, 10,14 since there is most likely actin and myosin cross-bridging throughout Before 6 12 24 48 72 96 120 144 0 1 2 3 4 5 U pp e r B ac k Run1 Run2 A Before 6 12 24 48 72 96 120 144 0.5 1.5 2.5 3.5 4.5 Lo w er B ac k Run1 Run2 B Before 6 12 24 48 72 96 120 144 Time (h) 0 1 2 3 4 5 m G lu te u s m a x Run1 Run2 C  Fig. 2. This represents changes in delayed-onset muscle soreness across time for (A) upper back and (B) lower back and (C) gluteus maximus. In all muscle groups there was a significant bout effect (p<0.05, not shown on the graph), with values for run 2 being consistently lower than for run 1. (1 = ‘normal’ and 10 = ‘very, very sore’). PG86-93.indd 90 10/3/07 3:27:25 PM SAJSM vol 19 No. 3 2007 91 the range of motion during the lengthening contraction. However, during low-intensity high-repetition aerobic- like eccentrics, such as downhill running, 6 it is proposed that most of the external load is applied at the end of the movement, producing a braking/shock absorbing function during the foot strike, with low resistance and minimal actin and myosin cross-bridging as the muscles (e.g. quadriceps) move through the swing-lengthening phase of the running motion. If the primary force is only applied at the end of the action, it is possible that the primary stress is on collagen and tendon structures outside the muscle fibre; 10 this would be supported by findings of Malm and colleagues, 11,12 who 27 Before 6 12 24 48 72 96 120 144 0 1 2 3 4 5 Run1 Run2 A. Gluteus m. Before 6 12 24 48 72 96 120 144 0 1 2 3 4 5 Run1 Run2 B. Hamstrings Before 6 12 24 48 72 96 120 144 Time (h) 0.5 1.0 1.5 2.0 2.5 3.0 3.5 Run1 Run2 C. m. Tibialis Before 6 12 24 48 72 96 120 144 Time (h) 0 1 2 3 4 5 Run1 Run2 D. Gastrocnemius Fig. 3. These represent changes in delayed-onset muscle soreness across time for (A) quadriceps (cross symbol repre- sents significant differences between run 1 and run 2 at each time), (B) hamstrings, (C) tibialis, (D) gastrocnemius. In all four areas, there was a significant bout effect (p<0.05, not shown on the graph) with values for run 2 being consistently lower than for run 1. (1 = ‘normal’ and 10 = ‘very, very sore’). PG86-93.indd 91 10/3/07 3:27:26 PM 92 SAJSM vol 19 No. 3 2007 suggest that after downhill running, inflammatory factors are present in muscle epimysium and that the focal injury does not exist in muscle. It is proposed that during high-force resistance-like eccentrics the primary damage is to the muscle fibre, while during low-force aerobic-like eccentrics the primary damage is to structures outside the muscle fibre, such as collagen and tendons. 10 So differences in mode of exercise could induce differences in the target of injury. 5 Whether this could induce differences in aspects of inflammation, such as differences in neutrophilia, is currently unknown. An alternate explanation for the lack of reduced neutrophil count in the present study, after run 2, could be that the body responds differently to a focal injury (biceps trauma) versus a more diffuse injury (stress to several major muscle groups such as quadriceps and gluteal muscle). Undoubtedly the internal neuro-endocrine milieu is vastly different during these different forms of exercise/injury, and the role this may play in neutrophilia is currently not clear. Although the focus has been on neutrophilia, monocytes/ macrophages form the second line of defense in acute inflammation. Many monocytes/macrophages are resident in tissue (ED2 + ), while many migrate from the circulation (ED1 + ). In the present study there were no differences in monocyte count between the two runs. However, there was a significant time effect with blood monocytes being elevated over baseline levels between 4 and 12 h after both bouts of exercise; these changes were remarkably similar to what has previously been reported. 21 The principle that increased numbers of circulating cells precede migration to injured tissue would be in keeping with the notion that there is a similar infiltration of monocytes after both bouts of eccentrics. 9 Creatine kinase Although CK does not correlate with histological evidence of skeletal muscle damage 23 it is still consistently used as an indirect marker of muscle damage. 6,24 Several notable ob- servations were seen in the present study, in response to the downhill running. An interesting finding was related to significant differences between run 1 and run 2 starting at 3 h after the downhill running. Previous studies, using downhill running, have generally taken blood samples starting at 24 h after the exercise bout. 2,3,12 We believe this is the first study to demonstrate that significant differences occur as early as 3 h after the downhill run. In the present study CK levels peaked between 9 and 12 h after both bouts. This early difference in CK seen after downhill running contrasts with differences reported after high-intensity resistance-like exercise (maximal exercise of elbow flexors). 6 After repeated bouts of elbow flexors, significant differences between CK levels after bout 1 and 2 are generally seen at a later time period 6 such as at 12 and 24 h 18 or at 3 and 4 d. 8 It is suggested that the significant differences in CK, in the present study, seen initially at 3 h after run 1 and run 2, as well as the time for peak values (9 - 12 h after run 1), were due to the mode of exercise. Downhill running undoubtedly increases metabolic rate, as is evidenced by increased heart rates and oxygen consumption, 6 both during and after the exercise, compared with exercise that involves high intensity/ low repetitions and that induces more focal injury. The increased metabolic rate could have resulted in a more rapid efflux of creatine kinase from the damaged tissue into the circulation. 16 In the present study, the overall finding of significantly lower CK values after run 2 concurs with previous studies on the repeated bout effect. However, when comparing peak CK values between the different types of eccentric protocols, values are consistently lower for the downhill running protocols. 6 The peak mean CK seen in the present study was approximately 1 200 IU.l -1 compared with a mean peak CK of approximately 3 500 IU.l -1 reported by Pizza et al. 18 The idea of lower CK levels being associated with eccentrically biased downhill running 6 would support the idea that there is less damage to the muscle fibers per se (as was suggested above) and possibly more damage focused on the extra- muscle collagen and tendon structures. 4 An additional observation is related to changes in CK over the entire period (before exercise through 144 h after). As stated earlier, there was an initial peak between 9 and 12 h and then a secondary reduced, but significant peak at 96 and 120 h. This biphasic pattern is similar to that reported by Schwane and Armstrong, 20 in which rodents ran downhill on a treadmill, and is also similar to what was previously reported after downhill running in human subjects. 21 Although speculative, it is suggested here that the initial peak reflects the primary mechanical injury, while the secondary peak reflects the secondary metabolic/biochemical injury. 7,14 Delayed-onset muscle soreness DOMS was assessed in 7 different muscle groups. The high- est levels of DOMS were reported in the quadriceps and the upper back. Such high levels were unexpected in the upper back. However, it appears that this area involves a balancing/ braking action during downhill running. Most soreness peak- ed at 24 h and then began to dissipate. However, DOMS remained elevated in the tibialis anterior and gastrocnemius through 72 h. In conclusion, a somewhat puzzling aspect of the comparisons between this study involving low-intensity, high- repetition aerobic-like eccentrics versus studies involving high intensity, low repetition resistance-like eccentrics, is that certain aspects of the repeated bout effect are similar (CK was significantly reduced, although less pronounced elevations were seen in this study; DOMS was also significantly reduced after run 2), while other aspects of this response differ (different responses in circulating numbers of neutrophils after run 2). It is suggested that future studies be more cognisant of the mode of eccentrics used when attempting to interpret the responses to tissue damage. PG86-93.indd 92 10/3/07 3:27:26 PM SAJSM vol 19 No. 3 2007 93 References 1. American College of Sports Medicine. Guidelines for Exercise Testing and Prescription. 6th ed. Baltimore, MD: Lippincott Williams and Wilkins, 2000. 2. Armstrong RB, Garshnek V, Schwane JA. Muscle inflammation: response to eccentric exercise. Med Sci Sports Exerc 1980; 12: S94-5. 3. Byrnes WC, Clarkson PM, White JS, Hseih SS, Frykman PN, Maughan RJ. Delayed onset muscle soreness following repeated bouts of downhill running. J Appl Physiol 1985; 59: 710-15. 4. Cleak MJ, Eston RG. Muscle soreness, swelling, stiffness and strength loss after intense eccentric exercise. Br J Sport Med 1992; 26: 267-72. 5. Eston RG, Lemmey AB, Mchugh P, Byrnes C, Walsh SE. Effect of stride length on symptoms of exercise-induced muscle damage during a repeat- ed bout of downhill running. Scand J Med Sci Sports 2000; 10: 199-204. 6. Eston RG, Mickleborough J, Baltzopoulos V. Eccentric activation and muscle damage: biomechanical and physiological considerations during downhill running. Br J Sport Med 1995; 29: 89-94. 7. Faulkner JA, Brooks SV, Opiteck JA. Injury to skeletal muscle fibers during contractions: conditions of occurrence and prevention. Phys Ther 1993; 73: 911-21. 8. Hirose L, Nosaka K, Newton M, et al. Changes in inflammatory mediartors following eccentric exercise of the elbow flexors. Immunol Rev 2004; 10: 75-90. 9. Lapointe BM, Fremont P, Cote CH. Adaptations to lenghtening contractions is independent of voluntary muscle recruitment but relies on inflammation. Am J Physiol Regul Integer Comp Physiol 2002; 282: R323-29. 10. Lindstedt Sl, Lastayo PC, Reich TE. When active muscles lengthen: Prop- erties and consequences of eccentric contractions. New Physiol Sci 2001; 16 256-61. 11. Malm C, Nyberg P, Engstrom M, et al. Immunological changes in human skeletal muscle and blood after eccentric exercise and multiple biopsies. J Physiol 2000; 529: 243-62. 12. Malm C, Sjodin B, Sjoberg B, et al. Leukocytes, cytokines, growth factors and hormones in human skeletal muscle and blood after uphill or downhill running. J Physiol 2004; 556: 983-1000. 13. McHugh M. Recent advances in the understanding of the repeated bout effect: a brief review. Scand J Med Sci Sports 2003; 13: 1-10. 14. Nosaka K, Newton M. Differences in the magnitude of muscle damage between maximal and submaximal eccentric loading. J Strength Cond Res 2002; 16: 202-8. 15. Nosaka K, Sakamoto K, Newton M, Sacco P. How long does the protective effect on eccentric exercise-induced muscle damage last? Med Sci Sports Exerc 2001; 33: 1490-5. 16. Peake JM, Nosaka K, Suzuki K. Characterization of inflammatory respons- es to eccentric exercise in humans. Exerc Immunol Rev 2005; 11: 64-85. 17. Pizza FX, Baylies H, Mitchell JB. Adaptations to eccentric exercise: neu- trophils and E-selectin during early recovery. Can J Appl Physiol 2001; 26: 245-53. 18. Pizza FX, Davis BH, Henrickson SD, et al. Adaptation to eccentric exer- cise: effect on CD64 and CD11b/CD18 expression. J Appl Physiol 1996; 80: 47-55. 19. Pizza FX, Koh TJ, Mcgregor SJ, Brooks SV. Muscle inflammatory cells after passive stretches, isometric contractions, and lengthening contrac- tions. J Appl Physiol 2001; 92: 1873-78. 20. Schwane JA, Armstrong RB. Effect of training on skeletal muscle injury from downhill running in rats. J Appl Physiol 1983; 55: 969-75. 21. Smith LL, Bond JA, Holbert D, et al. Differential white cell count after two bouts of downhill running. Int J Sports Med 1998; 19: 432-37. 22. Smith LL, Fulmer MG, Holbert D, et al. The impact of a repeated bout of eccentric exercise on muscular strength, muscle soreness, and creatine kinase. Br J Sports Med 1994; 28: 267-71. 23. Van der Meulen JH, Kuipers H, Drukker J. Relationship between exercise- induced muscle damage and enzyme release in rats. J Appl Physiol 1991; 71: 999-1004. 24. Warren Gl, Lowe DA, Armstrong RB. Measurement tools used in the study of eccentric contraction-induced injury. Sports Med 1999; 27: 43-59. PG86-93.indd 93 10/3/07 3:27:26 PM