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A climbing park is different from a traditional amusement park. In the climbing courses, you'll encounter obstacles that challenge your balance, coordination, and comfort zone. Here, everyone can find a climbing course that suits their skill level and experience. The courses are color-coded by difficulty, ranging from orange easiest to black most difficult , with light green, green, blue, and red as intermediate levels. The park offers 3 training courses, 2 orange, 2 green, 1 blue, and 1 red course. Each course provides fun and exciting challenges, including some thrilling aerial sections. With a total of 73 elements, 10 ziplines, and 6 courses, you're sure to feel butterflies in your stomach and experience a sense of achievement. The climbing park has an age limit of 10 years and requires a minimum height of cm. Whether you're a grandparent looking to climb with your grandchildren, parents wanting to spend quality time with your kids, or friends making unforgettable memories together, this is the place for you. Children's tickets are available from age 4. You can choose between a 3-hour ticket or a day pass, especially during the off-season. For children aged 4 to 6, an adult must accompany them and purchase a ticket. A jump tower is an exciting wooden structure where you can take a leap from a height. July - August: All days from August - September - October: All days from Note: With a 3-hour ticket, you can start either between or Please arrive early to be ready for your session. Select your preferred start time when booking your ticket. During the off-season, day passes are also available. Children aged must be accompanied by an adult who also redeems the ticket. Everyone who is going to climb must attend climbing training and follow the climbing park rules. Geilo Summer Park offers a wide range of activities for the whole family, including a climbing park, lift-accessed biking, frisbee golf,. Main navigation. Cross-country skiing in Geilo Cross-country tracks Courses and ski rental Food service cabins in winter. Accommodations Hotel Cabin Apartment Camping. Shops in Geilo Pharmacy and opticians Hardware stores Grocery store and liquor store Hobby and leisure Interior, furniture and kitchen IT and electronics Clothing stores Sports shops Beauty and wellness. Language Engelsk Norsk. Season Select your season Winter Summer. Home Book summer activities Climbing Park. Opening hours for the climbing Park and jumping tower The climbing park is open from June to the end of October, operating during the summer season. Opening hours Open every Saturday in June from - 6. October: All days from Note: With a 3-hour ticket, you can start either between or Avoid queues - Meet at the start time you have booked! Pre-booked tickets: Meet at the equipment location at the start time you have booked, get your ticket ready while you wait for the equipment. Drop in: Check available capacity in the information center and buy the ticket there before you go to the equipment location. The equipment place is located at the entrance to the chair lift. The height requirements for the different colors on the slopes are: Orange: Over 80 cm. Black: Over cm. Access to the climbing trails is not permitted for people who: weighs more than kg are pregnant is under the influence of alcohol or other drugs Children aged must be accompanied by an adult who also redeems the ticket. Favorite mark. Geilo Summer Park Geilo Summer Park offers a wide range of activities for the whole family, including a climbing park, lift-accessed biking, frisbee golf, Read more.

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Context Although using a helmet is assumed to reduce the risk of head injuries in alpine sports, this effect is questioned. In contrast to bicycling or inline skating, there is no policy of mandatory helmet use for recreational alpine skiers and snowboarders. Objective To determine the effect of wearing a helmet on the risk of head injury among skiers and snowboarders while correcting for other potential risk factors. Design, Setting, and Participants Case-control study at 8 major Norwegian alpine resorts during the winter season, involving injured skiers and snowboarders reported by the ski patrol and noninjured controls who were interviewed on Wednesdays and Saturdays. The controls comprised every 10th person entering the bottom main ski lift at each resort during peak hours. The number of participants interviewed corresponded with each resort's anticipated injury count based on earlier years. Main Outcome Measure Injury type, helmet use, and other risk factors age, sex, nationality, skill level, equipment used, ski school attendance, rented or own equipment were recorded. A multivariate logistic regression analysis was used to assess the relationship between individual risk factors including helmet wear and risk of head injury by comparing skiers with head injuries with uninjured controls, as well as to skiers with injuries other than head injuries. Results Head injuries accounted for injuries The effect was slightly reduced OR, 0. For the potentially severe head injuries, those who were referred to an emergency physician or for hospital treatment, the adjusted OR was 0. The risk for head injury was higher among snowboarders than for alpine skiers adjusted OR, 1. Conclusion Wearing a helmet is associated with reduced risk of head injury among snowboarders and alpine skiers. Alpine skiing and snowboarding are increasingly popular winter sports and are enjoyed by several hundred million people worldwide. However, the injury risk is high, 1 and head injuries are common in alpine skiers and snowboarders. In the absence of recommendations, helmet use is generally low among recreational skiers and snowboarders 15 , 16 although their use is higher among children. The purpose of our study was to examine the effects of helmet use on the risk of head injury among skiers and snowboarders using an uninjured, representative group of skiers and snowboarders as controls while adjusting for risk factors and potential confounders, such as age, equipment, ability, and sex. Also, we wanted to assess the effect of helmet wear on the risk of neck injuries. Our study was based on anonymized data from the Norwegian Ski Lift Association injury and marketing research databases. According to the mandate of the Regional Committees for Medical Research Ethics, projects that are based on records from regular treatment procedures are exempt from review. For this study, the chair of the Regional Committee for Medical Research Ethics of Southern Norway reviewed the study retrospectively and confirmed that the project would have been approved, had it been submitted for formal review at an earlier stage Kristian Hagestad, written communication, January 30, An injury was recorded when a skier or snowboarder was treated by or consulted with the ski patrol or first aid room staff after an accident in the skiing area during skiing or lift transport. To qualify for the ski patrol, the personnel are required to undergo a structured program of first aid education. Skiing ability was classified into 4 categories beginner, intermediate, good, or expert based on self-reported performance of turns. The anatomical location head, neck, shoulder, etc and injury type was recorded classified as fracture, dislocation, sprain, contusion, skin wound, or illness , as well as whether the patient needed transportation to a physician or hospital for further evaluation and treatment. Such patients were defined as potentially severe cases. For patients with multiple injuries, each injury was recorded separately. As a control group, noninjured skiers and snowboarders were interviewed in the same 8 ski resorts during the same season. The target number interviewed corresponded to the expected injury count from each resort, estimated from injury surveillance data from previous years. Every 10th skier or snowboarder waiting in line was interviewed to achieve a systematic sample of the population. The interviews were done every Wednesday and Saturday during the 4 winter months of by personnel who were not told the purpose of the study. The registration was done when lifts opened in the morning and after lunch ie, AM and PM. This is when most users enter the area, and the main lifts serve to feed a number of other lifts that take the skiers further into the mountain area to ski the runs available. Except for the injury-related information, the questions asked were the same as those for the injured skiers ie, age, sex, nationality, equipment type, use of helmet, previous ski school attendance, rented or own equipment, and skiing ability. In addition, a second systematic sample of noninjured skiers and snowboarders was interviewed about risk-taking behavior, using the same approach as that used to select noninjured controls as described above. Skiers or snowboarders entering the bottom main ski lift in the same ski resorts were asked if they considered themselves to be a cautious or risk-taking skier or snowboarder. Helmet use, age, sex, nationality, equipment type, and skiing ability were also recorded in this group. Fisher exact tests were used to compare characteristics between groups. We used logistic regression analysis to estimate the relationship between helmet use and head injuries. To select potential confounders, we performed univariate analyses of the relationships, first between head injuries and risk factors and then between helmet use and risk factors. The factors found were age, sex, nationality, skiing ability, and type of equipment. Factors such as skiing instructions and ski rental did not qualify as a confounder. Analyses of the protective effect of helmet wear were done using noninjured skiers or snowboarders and skiers or snowboarders with other injuries than head injuries as controls. Tests of interaction between helmet use and risk factors for head injuries were done by adding cross-product terms of helmet use and dummy variables for categorized variables. Two-way interactions were also performed by adding cross-product terms of 3 factors, such as age, equipment and helmet use, including all 3 2—factor cross-product terms, as well. If significant 2-way interactions were not identified, the term was eliminated and 1-way interactions with helmet use were tested collectively and thereafter singly. Likelihood ratio tests were used to detect interaction effects. All P values are 2-tailed. Of the patients with injuries recorded, patients Head injuries accounted for Ten head injuries occurred among those whose equipment was unknown. Patients with head injuries and controls differed on a number of descriptive characteristics Table 1. Of the patients with head injury, were referred to a physician or hospital by the ski patrol for further assessment or treatment potentially severe injuries , and the characteristics of this subgroup did not differ from individuals with less severe head injuries Table 1. Table 2 compares the same characteristics with respect to helmet use or not within the control group. It shows that many of the same risk factors were associated with head injuries as well as with helmet use, thus representing potential confounding factors for the relationship between head injuries and helmet use. The OR for head injuries vs helmet use was fairly consistent across subgroups of age and equipment, adjusting for sex, skiing ability, and nationality. Among alpine skiers, the OR was 0. For snowboarders the corresponding ORs were 0. After elimination of the second-order term in the model, no 1-way interaction remained significant P ranging from. Table 3 shows the relationship between participant characteristics and risk of head injuries analyzed using multiple logistic regression analyses. Helmet use was associated with a lower risk of head injuries OR, 0. The crude OR for helmet use was 0. When adjusted for age, the OR was reduced to 0. For head contusions and fractures, the OR for helmet users vs nonusers was 0. When considering subgroups of injuries occurring in different ski locations, the OR was 0. An additional analysis using skiers with other injuries than head injuries as controls vs all skiers with head-injuries revealed an OR for helmet wear of 0. Similarly, when skiers with head injuries only were compared with skiers with other injuries than head injuries as controls, the effect of helmet wear was 0. There were 62 neck injuries, 27 in alpine skiing 0. Of the 62 neck injuries, 14 wore a helmet and 46 did not 2 unknown. After adjustment for age, sex, skiing ability, equipment, and nationality, the use of helmets was also associated with a lower risk of neck injuries, but this association was not statistically significant OR, 0. Among the subgroup of controls who were interviewed about risk-taking behavior, wore a helmet and did not. A total of Risk takers were more likely to wear a helmet OR, 1. Two recent case-control studies suggest that helmets can protect skiers and snowboarders against head injuries. The first study by Macnab et al, 16 which was based on a group of patients younger than 13 years with injury to their head, face, or neck, compared a simple count of the proportion of helmet users in this group with random skiers and snowboarders at the same resort. They reported that children who did not wear a helmet experienced an increased risk of head, neck, or face injury combined. However, the study was too small for conclusive statements regarding the effect on head injury alone and did not control for potentially important confounding factors. They compared patients with head injuries cases to patients with other injury types controls. This result was replicated in our study when we used patients with other injury types as controls. Moreover, by using a noninjured, representative control group to correct for potential confounders, the current study also addressed the more general question of whether helmets were protective for all skiers and snowboarders, irrespective of whether they experienced other injuries. Our analysis identified beginners, male sex, youth, and snowboarders as groups with increased risk of head injuries but also showed that the protective effect of helmet use is consistent across groups. That cautious people tend to wear helmets and that it is caution that confers the protective effect is an issue of concern when interpreting the results from case-control studies on the protective effect of helmet use. The question used to assess risk-taking behavior has not been formally validated but appears to have face validity. Our data show that risk takers were more likely to use a helmet within all disciplines, age groups, and skill levels. This means that the true helmet effect may be greater than our estimate and strengthens the conclusion that helmet use is associated with a reduced risk of head injury. It should also be noted that the helmet effect was as great in the presumably wildest activity areas—the snowboard park and off-piste—as it was for injuries in groomed runs, where the more cautious skiers and snowboarders are more likely to be. One concern raised with helmets is whether they lead to an increased risk of neck injuries, especially among children due to the relatively higher mass added to the head. In our study, there was a trend toward a lower risk of neck injuries with helmet wear. Hagel et al, 19 again using a population of skiers and snowboarders with other injuries as their control group, suggested that the risk of cervical spine injuries may be increased. Obtaining a control group representative of all skiers and snowboarders at risk is difficult. All users entered there, and many users would end up there after a run, even after going off-piste or in the snowboard park. We selected Wednesdays and Saturdays to sample the control group to compensate for differences in user characteristics between weekdays and weekends, and matched the number of controls to the expected injury count in each ski area. However, even this elaborate approach does not take skiing distance into account, and if helmeted skiers ski less, the helmet effect will have been overestimated. Potential confounding by type of run or weekday of injury may have been accounted for, at least in part, by the factors already adjusted for. This would also be the case if helmeted skiers who sustained a head injury were less likely to report their injury than those not wearing a helmet. We have not assessed the number of injured skiers and snowboarders that bypass the ski patrol for their injuries. Studies have shown that self-reported injuries may be up to 10 times higher than injuries recorded by ski patrols, but those missed by ski patrols were minor. Recall bias is not likely to have been a significant factor because interviews were conducted on the spot, usually within a few minutes after the injury. Although we do not know how a stressful injury situation may have affected how skiers report their skiing ability or ski instruction, most other factors including helmet status could be observed directly by the ski patrol. Helmet use is associated with reduced risk of head injury among snowboarders and alpine skiers. There was a trend toward a lower risk for neck injuries with helmet wear. Author Contributions: Drs Sulheim, Holme, and Bahr had full access to all of the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. Critical revision of the manuscript for important intellectual content : Sulheim, Holme, Ekeland, Bahr. Data collection was funded by the Norwegian Ski Lift Association. Role of the Sponsor: No funding agency has been involved in the design and conduct of the study; data analysis or interpretation; manuscript preparation or review. Table 1. Table 2. Table 3. Hunter RE. Skiing injuries. Am J Sports Med. Snowboard head injury: prospective study in Chino, Nagano, for two seasons from to J Trauma. Head injuries in skiers and snowboarders in British Columbia. Can J Neurol Sci. The dangers of snowboarding: a 9-year prospective comparison of snowboarding and skiing injuries. Acta Orthop Scand. Severe skiing injuries: a retrospective analysis of patients including mechanism of trauma, severity of injury, and mortality. Severe snowboarding injuries. Spectrum of injuries from snowboarding. Snow-related recreational injuries in children: assessment of morbidity and management strategies. J Pediatr Surg. Injuries to the nervous system and spine in downhill skiing. Can J Surg. Bicycle-associated head injuries and deaths in the United States from through how many are preventable? Helmets for preventing head and facial injuries in bicyclists. Cochrane Database Syst Rev. Centers for Disease Control and Prevention. Injury-control recommendations: bicycle helmets. American Medical Association. In-line Skating. Report Torjussen J, Bahr R. The prevalence and predictors of helmet use by skiers and snowboarders at ski areas in western North America in Inj Prev. Injuries in alpine skiers, Telemarkers and snowboarders at Norwegian ski resorts. Skiing, Trauma and Safety. Vol Neurologic injuries in skiers and snowboarders. Semin Neurol. Effectiveness of helmets in skiers and snowboarders: case-control and case crossover study. Skiing injuries in children, adolescents, and adults. J Bone Joint Surg Am. Lower extremity equipment-related injuries in alpine recreational skiers. Alpine skiing injuries: an epidemiological study. Reduction of injuries in downhill skiing by use of an instructional ski-video: a prospective randomised intervention study. Knee Surg Sports Traumatol Arthrosc. Save Preferences. Privacy Policy Terms of Use. This Issue. Citations View Metrics. X Facebook More LinkedIn. Original Contribution. Back to top Article Information. Financial Disclosures: None reported. Access your subscriptions. Access through your institution. Add or change institution. Free access to newly published articles. Purchase access. Rent article Rent this article from DeepDyve. Sign in to access free PDF. Save your search. Customize your interests. Create a personal account or sign in to:. Privacy Policy. Make a comment.

Geilo buying MDMA pills