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The Big Book of Endurance Training and Racing
The Big Book of Endurance Training and Racing
The Big Book of Endurance Training and Racing
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The Big Book of Endurance Training and Racing

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  • Endurance Sports

  • Overtraining

  • Endurance Training

  • Nutrition

  • Overtraining Syndrome

  • Hero's Journey

  • Mentorship

  • Self-Discovery

  • Overcoming Obstacles

  • Dangers of Overtraining

  • Overcoming Adversity

  • Self-Improvement

  • Mind-Body Connection

  • Mentor

  • Power of Perseverance

  • Endurance

  • Muscle Imbalance

  • Health

  • Injury Prevention

  • Stress Management

About this ebook

Are you a triathlete, runner, cyclist, swimmer, cross-country skier? Learn how to stay healthy, achieve optimal athletic potential, and be injury-free.

Dr. Philip Maffetone’s approach to endurance offers a truly “individualized” outlook and unique system that emphasizes building a strong aerobic base for increased fat burning, weight loss, sustained energy, and a healthy immune system. Good nutrition and stress reduction are also key to this commonsense, big-picture approach.

In addition, Dr. Maffetone dispels many of the commonly held myths that linger in participatory sports—and which adversely impact performance—and explains the “truths” about endurance, such as:
  • The need to train slower to race faster will enable your aerobic system to improve endurance
  • Why expensive running shoes can actually cause foot and leg injuries
  • The fact that refined carbohydrates actually reduce endurance energy and disrupt hormone balance
  • And more.

If you are looking to increase your endurance and maximize your athletic potential, The Big Book of Endurance Training and Racing is your one-stop guide to training and racing effectively.
LanguageEnglish
PublisherSkyhorse
Release dateSep 22, 2010
ISBN9781628731316
The Big Book of Endurance Training and Racing
Author

Philip Maffetone

Philip Maffetone has been a private practitioner, health and athlete coach and consultant, published independent researcher, respected pioneer in the field of complementary sports medicine, and internationally recognized educator and author in the fields of nutrition, biofeedback, exercise physiology, and athletic training over the course of his forty- year career. Since 1977, he has used the term “ overfat” and has recommended low-carbohydrate and healthy fat eating.

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  • Rating: 5 out of 5 stars
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    This is the bible of endurance training books. It is a must read for beginners to avoid common mistakes and avoid injury while training, but also a good read if you want to take your training to a new level as a professional athlete.

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The Big Book of Endurance Training and Racing - Philip Maffetone

INTRODUCTION

My Personal Journey on the Road to Endurance

Life is a journey of endurance, full of unexpected surprises. Little did I know growing up that one day I would become a holistic practitioner who would spend many wonderful years working closely with endurance athletes, ranging from beginners to seasoned veterans, including some of the world’s greatest competitors. These athletes include triathlon champions Mark Allen, Colleen Cannon, and Mike Pigg, world-class distance runner Marianne Dickerson, and the late running guru Dr. George Sheehan.

The irony is that I started out as a high school sprinter competing in the 220-yard event and shorter distances—a far cry from being an endurance athlete myself, or even knowing much about the human body or understanding its potential through proper training, stress management, and diet.

Through years of trial and error, experience, immersion in the literature of exercise physiology, Eastern philosophy, and treating patients and athletes, I continued to refine and expand upon what I consider the big-picture approach to endurance sports. But before offering you a wealth of information on how to become a better endurance athlete, allow me to first recount my own personal story, which reflects the reason why, to this day, I encourage all athletes to never neglect their health for the sake of performance. Both fitness and health are intertwined in a deeply significant way, a fact that became entirely apparent to me soon after I ran the New York City Marathon in 1980.

I started running track in high school in the 1960s, and those twenty-two or twenty-three seconds going all-out on cinders in my spikes represented the full extent of my endurance. Until the end of my sophomore year in high school, I was not physically active; gym class was embarrassing because I was uncoordinated and could not do the things most other kids did. Even my academic world was disastrous, since I was a poor student just barely moving on to the next grade level each year, only thanks to summer school. But puberty and a surge of natural testosterone fortuitously came into my life, and during the last week of tenth grade, our gym class had a fitness test—running 600 yards. Without training or preparation, I beat everyone. The following year I joined the track team and began a streak of nearly undefeated racing that extended all the way into college.

Along the way, I had a few bad races. In my senior year, for example, I was the only runner from my high school to qualify for the biggest meet in New York State. After a cafeteria lunch of the usual junk food, I left with the track coach for the long drive to the meet. Once there, I ran several heats, easily winning each race to keep progressing until I made the finals. But I hadn’t eaten anything since lunch. The final race was well into the evening and I was famished. Walking to the starting line, I felt weak and shaky from lack of food. And, I didn’t see my starting blocks, which the rest of the sprinters had already set up. The official told me to hurry across the track and fetch my blocks. As soon as I returned, the race started. I sprinted about 150 yards, and, realizing that I wasn’t going to win, I jogged to the finish dead last; the winning time was a slow 23.5 seconds.

After high school graduation, I decided to go to college for one reason—to run track—despite my poor grades. My primary goal was to reach national levels, with thoughts about making the U.S. Olympic team.

Much of my training time at college was spent on my own: an easy warm-up lap or two around the quarter-mile track, ten or twelve short sprints, and a cool-down lap. I don’t recall many of the smaller track-and-field races with nearby colleges. I would just show up and run fast, winning most of them. With what seemed like too much extra time on my hands, I also wanted to use my leg speed and newfound overall athleticism to play football and baseball, but was prevented from doing so by my track coach who thought I’d get injured.

I started out as a sprinter in high school.

I succeeded in qualifying for the nationals during the collegiate indoor track season, having raced on many old wooden tracks to get there. But I had to run even shorter distances like the sixty-yard sprint to accomplish this goal. At the season-ending race, I was one of three runners in a photo finish—I placed third. But after that race, I lost interest in training and racing. I also dropped out of college. Studying wasn’t for me. I was ready to move on with life.

I was now living in the same small upstate New York town where I grew up, ironically near the high school track where I ran so well. I found a good job, with benefits, working for the phone company, which required me to test newly installed equipment inside the telephone buildings. I soon got married, started a family, and tried to maintain as much sports activity as possible, joining an amateur football team as a wide receiver and participating in baseball, playing alternately at most positions. I also swam freestyle, always short distances, and was nearly as good a competitor as in my earlier track days.

During this time I also became interested in exercise physiology and nutrition. Perhaps my childhood contributed to this desire. My mother would often listen to nutrition expert Carlton Fredericks on the radio, and later, my father became fascinated with Rodale’s organic gardening ideas and planted a family vegetable garden.

I read Adele Davis’s books. In the late sixties and early seventies, she was recognized as a nutritional sage. I also worked part-time in a health food store and joined a natural foods co-op. I had already been studying Eastern philosophy, and now it seemed even more important, as the only image of health that personally made sense was the holistic one.

One day I had what could only be described as a powerful vision—that I needed to go back to school and become a doctor to help people. It was so strong an epiphany that the next day I gave my two-week notice to the phone company. I planned to complete my undergraduate work at a local college and found an evening job in a restaurant. My grades improved slightly as I learned more about human biology and could relate it to my own health. Eating better was a significant part of becoming a more attentive student. Still, my poor grades overall made it difficult to get into any professional school. I met a chiropractor who knew the dean of the National University of Health Sciences in Chicago. There I could study nutrition, sports medicine, and other related topics, and its doctorate of chiropractic would allow me to one day practice as a physician.

Uprooting my family, now with two young children, from New York to Chicago was quite stressful. I found a job as night watchman at a factory, the midnight to 8:00 AM shift, and obtained school loans to pay for tuition and other costs. The school offered the option of a summer semester, enabling students to complete the five-year program in three and a half years, and I opted for the accelerated program. The professional school curriculum was twice as rigorous as that of undergraduate work. The extra study time required overwhelmed me. One could not, for example, learn enough about the body from human dissection class without also spending the entire weekend studying the incredibly intricate details of just where each muscle attached, the delicate structure of the body’s joints, and the complex display of nerves running throughout the body.

But it was my disappointment with the philosophy of the chiropractic profession and its narrow range of assessment and therapeutic options that led me to call my old boss at the phone company and ask for my job back. He said my position was there if I wanted it. That evening, while pondering this choice, I went down to the basement of our on-campus apartment complex to do laundry. Accidentally going into the wrong door, I encountered a group of students listening to a lecture on muscles and movement, and how nutrition played a key role. Now I got really excited. Exposure to this kind of information was the original reason I had sacrificed so much.

Despite the long hours of classes, the graveyard factory shift, and my family responsibilities, it was studying topics outside the regular curriculum that became the priority. Chicago was home to a proliferation of weekend professional seminars regularly offered by medical doctors, osteopaths, chiropractors, acupuncturists, and others who taught about natural hands-on healing, diet and nutrition, and exercise. Exposure to all these topics complemented my studies of anatomy and physiology, biochemistry and pharmacology, and diagnosis. While the National University of Health Sciences was considered overly medical by many chiropractors—because it taught in a very scientific way and included much of what medical students study—it still held to rigid ideological views, an unyielding approach that I was uncomfortable with. For example, the school’s curriculum insisted that the spine was the cause of many health problems, and not lifestyle considerations such as nutrition and exercise.

But the learning I picked up at the seminars helped balance my education. The study of anatomy insisted that the bones of the skull were fixed, but now I discovered from osteopathy that the skull’s bones could move with the breath and other muscle motions, which offered important therapeutic possibilities. I learned that the brain, if injured, not only could recover but could improve in cognition and function, and with age. And muscles, which commonly get out of balance and can take weeks or months to rehabilitate, can be corrected easily and quickly through various types of hands-on treatment.

Yet even with all that I was learning, both in school and on weekends, I was still missing something: putting all that information into actual practice. I simply could not wait for graduation, so after a short time, I began treating people in my apartment—a sort of underground clinic. My first patients were fellow students, then people from the local community. I would often see this one classmate jog past my apartment to and from his daily workout. He always seemed exhausted upon his return compared to how he looked when he first started. One day I asked him if I could evaluate him, and he agreed. His body was quite beat up after his run—high heart rate, muscle imbalance, poor gait, and knee pain. I began to study how this could happen and became even more interested in exercise physiology.

Unfortunately, in 1976, with less than a year left of school, I physically, chemically, and mentally fell apart. The cumulative stress had caught up with me. One day I found myself in the hospital emergency room, and the physicians were not going to let me leave because I was so sick. My muscles had severely deteriorated, the intestines had shut down, and I was dangerously anemic. Because my immune system wasn’t working, my whole body was chronically inflamed. Yet I needed to travel to New York to take the state boards in order to get my license to practice. After I spent a week in the hospital, the doctors still would not let me leave. So I removed the IVs in both arms, got dressed, and arranged for a ride to the airport. I took the two-day exam, later finding out I passed, but was too sick and weak to return to Chicago and had to be hospitalized in New York.

I now weighed only ninety-seven pounds—a precipitous loss of sixty pounds in less than a year. Despite being bedridden in the hospital, I wanted to watch the Montreal Olympics on television, especially the track events. Yet I was barely able to reach the television switch and was too weak to turn it on. The nurse came in to help me. Jealously watching these Olympic athletes in action, I wondered how my health could so rapidly deteriorate. I wasn’t even thirty years old.

Soon after my return to Chicago, I made an appointment with a doctor in Detroit, who had taught a seminar I’d attended. Dr. George Goodheart offered to treat me without charge during my three-day visit, and allowed me to closely observe his treatment of patients, most of whom had flown in from other areas of the country and the world. Dr. Goodheart had developed a form of biofeedback assessment called applied kinesiology, which combined manual muscle testing with a variety of hands-on therapies, such as manipulation, acupuncture, and cranial therapy, with nutrition and other treatment methods. I had already used some of these approaches in my illegal student practice with good results, but never imagined I would see such extreme cases of ill and injured patients getting better in such a short time, including me. My initial blood test showed an alarming blood hemoglobin level of 7.1, low enough to require a transfusion (which never helped). But Dr. Goodheart said my blood test would improve. At the end of the third day, my blood test had reached 11—so unbelievable that, soon after returning to Chicago, I had the blood tested again to see if the result was true. Having studied hematology, I knew that it would take months, not days, to improve the blood cells. But mine was now 11.8! I was even more convinced that the methods of evaluation and treatment I was learning were more powerful than I had imagined. And, it provided me with the enthusiasm and confidence I never got from academic studies. This realization coincided with the beginning of my own physical recovery. In a short time, I further fine-tuned my diet and nutrition, and began to walk for exercise. At first, walking an easy ten minutes was almost impossible. But as I progressed, my muscles started to reappear and I continued improving. I gained most of my weight back.

In 1977, I moved back to New York with my family and entered private practice, once again living near the track where I had excelled as a high school sprinter. I soon began seeing a variety of patients, old and young. Some suffered from joint or back pain or had intestinal problems, not unlike my own for so long. My approach was simple: spend all the time necessary evaluating each patient as an individual, and once it was clear what the causes were, the treatment part was often quick and easy. I had a whole tool chest of possible therapies, from traditional physical remedies to diet, nutrition, stress management, even employing exercise as a therapy. It was a matter of matching the most appropriate therapy with the patient’s particular needs. Because of my truly holistic approach, and because many of these patients responded quickly, my referral practice built quickly.

The experience of having once been a patient was one of the most important lessons that enabled me to succeed with my own patients. A common complaint of patients is that their doctors don’t listen to them, don’t take their seemingly irrelevant complaints seriously, and simply treat their symptoms without finding the root cause of their problem. This is exactly what had happened to me when my body shut down. Doctors kept treating my symptoms, the reason I never recovered under their care. In some ways, I felt almost lucky to have experienced being a patient as part of my professional training. Health-care professionals who have never been patients are not often able to relate to certain aspects of what a patient really feels. I vowed to be an exception.

Local athletes began showing up at my office. Typically, an injury had sidelined them and they were looking for help. In fact, many visited me as a last resort after seeing different specialists. My approach was always the same: spend all the necessary time assessing them, then apply the most effective treatment.

One day, the president of the local Road Runners Club showed up. He was a firefighter who had fallen through the roof of a burning house. He had multiple physical injuries, especially in his back, yet was determined to run in the New York City Marathon, only several weeks away. I was able to fix his injuries and get him running without pain by using many of the therapeutic tools of evaluation and hands-on treatment I’d learned in recent years, especially by balancing his injured muscles. He completed his race with ease.

More and more distance runners from the region began filling up my waiting room as word spread of my successful and unconventional approach to injury treatment. Gradually implementing various biofeedback tools, I began measuring many aspects of human physiology in athletes, from heart-rate changes and breathing to the brain’s control over muscle function. I also learned another vital component to my work—that eliminating a simple or serious injury was only half of my job. The other half was knowing how the dysfunction happened and how to prevent its recurrence. This meant understanding how an athlete worked out, taking all the information I learned through my examination and treatment, and using that to make appropriate changes in training and competition.

My exposure to more and more runners led me to take up personal coaching, but I made sure that coaching was nothing like the traditional process of giving athletes training schedules and encouraging them to race harder. Instead, my coaching style was to help them be their own coach while providing objective feedback. They would coach themselves with my input, which helped them become more intuitive and instinctual about their body.

As my own health continued to improve, I entertained the notion of running in the New York City Marathon. By then, I had been walking regularly for more than two years. The marathon was six months away, and that seemed like plenty of time to train for it. So I began slow jogging in the middle of my walks, gradually making more of the one-hour workout an easy run. I monitored my heart rate, wore flat running shoes, and always walked at the start and the end of the session for a proper warm-up and cool-down. Eventually, I got up to two hours for my longest run of the week. While I had a sense of the distances I covered, my training was based on time.

It was a cool, overcast morning on race day for the New York City Marathon. The race started with a cannon blast so loud it shook the Verrazano Bridge. The crowd of 18,000 runners began to move and I was among them. All went well through the first ten miles. The excitement swept me along at a slightly quicker pace than I’d planned, yet I felt great. As expected, by fifteen miles I felt tired but was able to continue. Within the next couple of miles, however, I began to shiver. Despite drinking plenty of water, I felt dehydrated. And I was craving cotton candy. At eighteen miles, I stopped to check my feet. They were numb, and I wanted to be sure they were still there. My hamstrings are cramping, I said out loud. Suddenly, I realized I wasn’t thinking rationally, and all I could remember was my goal to finish the race and prove to myself and others that I was healthy.

Alarmed by how awful I looked, two paramedics tried to remove me from the course. But I wouldn’t let them. Somehow, I painfully fought my way onward. I have very little memory of those last few miles, but I’ll always remember the finale. It included a minor collision with a television cameraman in Central Park. The crowds got louder, and then I had a clear view of the finish line.

A finisher’s medal was hung around my neck. I cried with joy over the ultimate success of passing my four-hour endurance test. But the next moment I discovered myself herded into the first-aid tent. It looked like a war zone. There were casualties all around me. Doctors and nurses were running in and out. Sick-looking runners lying on cots groaned in pain. Ambulances came and went. I thought to myself, Are these people really healthy? And am I? I realized then that running the marathon had not proven my health at all. I was fit enough to run 26.2 miles. But clearly fitness was something quite different from good health. This critical concept will be discussed in much greater detail throughout this book; yes, too many endurance athletes wrongly assume that being super-fit or posting fast times is the same as being healthy.

Soon after the New York City race, I also began lecturing on various topics in holistic fitness and health, first at the local library, an aerobic dance studio, and a health food store, then at running clinics. I also began writing professional papers to present at conferences, where all types of health-care professionals began to adopt my holistic approach and began practicing it with their own patients. Gradually I received more invitations to races, such as the Bermuda Marathon, where I met Dr. George Sheehan, who was also a speaker. A cardiologist and runner, he was a very influential figure in the running community because of his regular columns in Runner’s World and other publications. He was philosophical and humorous when writing about the curious passions and obsessions of runners. He became intrigued with my implementation of heart-rate monitors. Dr. Sheehan later came to my office to see firsthand my work with athletes.

It wasn’t long before I began to be contacted by swimmers and cyclists, and later triathletes. These calls came from all over the United States, including San Diego, California, Boulder, Colorado, and Florida. I eventually set up athlete workshops of varying lengths—a day to a week—in these and other locations, combining one-on-one work, lectures, group runs, and bike rides to evaluate training, and spending time at the pool watching stroke mechanics.

Working with triathletes represented a unique experience compared to single-sport athletes. In this event, an athlete must train in three different activities: swimming, biking, and running. From a physiological standpoint, this type of cross-training has additional built-in benefits over single sports. The three activities are neurologically very different, with the brain responding uniquely to each different sport. Cross-training provided a better-rounded and balanced training response. In addition, each sport could be used to help manipulate the body differently. Clearly, this kind of triathlon training provided more fitness and health potential than the sum of all three sports. Swimming, for example, could also be used to help the body in its physical, metabolic, and other types of recovery following a longer run or bike ride. In particular, a long-distance triathlon was an accumulated increase of physical intensity, maintaining high aerobic activity in the swim and bike, and only becoming anaerobic in the run. These observations became important strategies to help the athletes I worked with succeed.

One endurance athlete who visited my clinic was a young, extroverted, blonde, and supremely talented triathlete by the name of Colleen Cannon. In a short time, she was able to go from a forty-minute 10K to about thirty-five minutes and started performing much better on the triathlon circuit. She also referred other triathletes, including a promising San Diegan: Mark Allen, who had yet to win the Ironman.

Another endurance athlete who came to my office for treatment and coaching was ultramarathoner Stu Mittleman. I had met Stu the day before at the pre-registration for a short-distance triathlon that he planned on entering. But he had a painful foot problem and was going to withdraw from the race. He asked me how long it would take to heal so he could race again. I told him that his problem would be easy to correct, and showed him how, eliminating the pain by manipulating the foot and working on the muscles that caused the problem. The next day, he completed the triathlon without difficulty.

I then began to work closely with Stu. I encouraged him to alter his training, use a heart-monitor, and improve his diet. Like most endurance athletes I’ve worked with, Stu taught me a lot about human performance. Watching him train made me feel like a scientist studying a human lab animal, especially observing him going round and round the track. Any time I saw a minor deviation in his gait or stride, he would take a pit stop and we’d correct the problem. Together, we prepared for the World Six-Day Race Championships in La Rochelle, France. In this, his biggest ultra event to date, he placed second overall out of a field of the world’s top two dozen ultrarunners, reaching almost 100 miles a day for six consecutive days—all while on a 200-meter indoor track. For the entire time he was running, I was stationed just off the track. My job was to keep him balanced as the race progressed—much like the pit-crew in a racecar event. When his energy fell, I would prepare certain food or drink to match his needs. I also monitored his heart rate and breathing, getting feedback about even the most subtle signs and symptoms, and even listening to the sounds of his footsteps as he ran past me on the track. I could associate certain changes in the sounds of his running with specific muscle imbalances.

During this period of working with endurance athletes, I also trained racehorses, using a heart-rate monitor to develop their natural endurance. Despite the obvious differences in structure, horses, if you imagine them standing on their back legs, are remarkably similar to humans. Much of their physiology is similar to human athletes, too. In many ways, horses were easier to treat than their human counterparts.

I was privileged to work with racecar legends Mario and Michael Andretti and numerous other drivers in preparation for such events as the Daytona twenty-four-hour race. I knew that they required significant endurance and fat burning to prevent their heart rates from rising too high during racing. Their brain function was also an important focus, and I helped to improve eye-hand coordination, quick thinking, and focus. I also gave a seminar to the Navy SEALs’ basic training instructors, and spent considerable time teaching the endurance pilots who flew the stealth bombers on very long missions. I even got to fly the stealth simulator.

Throughout my growing practice, travel with athletes, lectures, and my newly emerging writing career, I continued with my own running, entering many road races from the mile to the marathon, steadily improving year after year to very respectable age-group finishes. I also added swimming to my routine, and biking, competing in some shorter duathlons, triathlons, and swim events.

Yet as my lecturing and work with athletes took me on the road more often, and on longer international trips, such as Europe, Japan, and Australia, it became more difficult to maintain a high level of fitness. By the early 1990s, I stopped competing; even my training was significantly reduced. I finally had to reduce my work on all fronts by reducing my clinic hours and limiting travel to select events like the Ironman in Kona, Hawaii.

The last time I was on the Big Island of Hawaii was in 1995, when Mark won his sixth and final Ironman. I was in the lead media van (which featured the radio broadcast of the Yankees winning the World Series against the Braves).

In 1997, I closed my private practice and continued consulting and lecturing, while I spent a year writing a textbook called Complementary Sports Medicine. Soon after this book was published, I had another vision of sorts, not unlike the experience that told me to quit my job at the phone company and become a healer. I woke up one morning with an intense desire to become a songwriter, despite never playing an instrument or singing or knowing anything about songwriting. All I had was music in my head, which had been a lifelong activity. Within a week of this epiphany, I got a surprise call from powerful and influential recording music producer Rick Rubin, who wanted to become a patient. I told him I no longer practiced, but that I had just become a songwriter. We agreed to help each other in our respective endeavors. I was soon spending considerable time with Rick in Los Angeles, one of the great music capitals of the world. I was exposed to many great songwriters and his clients, including Neil Diamond and Diane Warren, and to groups who wrote their own music, such as the Dixie Chicks, System of a Down, and Audioslave. I became Johnny Cash’s doctor, trying to save him from declining health and an over-reliance on physician-prescribed drugs. I ultimately recorded my first songs in Nashville. And for a short period, I was the wellness doctor for the Red Hot Chili Peppers, traveling on a world tour with these four great musicians, and treating them like the endurance athletes they were.

During this time I also began measuring brain waves to show music’s significant effect on the brain. Not surprisingly, the production of the brain’s alpha waves, something humans have strived to do for thousands of years, was not just healthy, but important for athletes—for stress management, increased performance, and injury rehab.

While on the fast track to learning guitar and piano, and busy writing songs, I came to realize that my time living in the Hollywood Hills was much too stressful. I eventually reached a compromise by moving to a small mountain town in southern Arizona within a reasonable drive to Los Angeles so I could continue regular music recording and maintain my holistic work with Rick.

At an elevation of 4,500 feet, the area where I live is beautiful; it’s quiet and serene. Planting a large vegetable garden was a wonderful experience, and I continue to work on my music and have so far produced two CDs. Most importantly, I got back in great physical shape by avoiding as much physical, chemical, and mental stress as possible. While I haven’t returned to my former level of ability, I feel that I am in the best health of my life. Depending on time of year and desire, I try to do an hour or two of physical activity every day. This might include hiking and biking in the mountains, swimming, or strength exercises.

And, while writing this on a warm winter afternoon, I occasionally look out from the window in my bedroom office at the majestic snow-capped Santa Catalina Mountains. I hear music playing in my head.

Section

ONE

Building Your Endurance Foundation

CHAPTER 1

WHAT IS ENDURANCE?

To be human is to possess endurance. It’s built into our genes. One of the primary ways we’ve survived as a species is thanks to the role endurance has played in our own evolution. With bipedal and upright posture, feet designed for walking instead of climbing and hanging from tree branches, and the ability to generously sweat, which prevents the body from overheating, early humans were able to travel long distances without fatigue, heat exhaustion, or injury. The search for food or water could lead to newer life-sustaining environments many miles away.

If, over the course of several million years, natural selection has given us the gift of endurance, it is only recently that sports science has begun to fully examine what it means for an athlete to go far at a consistent intensity. But what accounts for the physical differences among us regarding endurance? Why are some of us faster? Why do some of us excel at shorter distances? Or others race better in longer ones?

While genetics may dictate some of these performance differences, we actually control much of our natural athletic expression through the training and lifestyle habits we choose. Making the right decisions brings out the built-in endurance we already have in our bodies. We increase our endurance by being both fit and healthy.

By looking at the whole body and fine-tuning all of its functions, one can automatically improve endurance. To have great endurance is to be holistic. If you want to achieve optimum endurance—the path to achieving your athletic potential—balancing the whole body is key to bringing out the endurance power within. Many factors contribute to and create our endurance, from muscle function and burning fat, to the various nutrients we consume and the intricate workings of our brain. This book discusses dozens of these factors and shows you how to use them to improve endurance. The optimal working of all these factors is important, and if one is deficient, endurance diminishes. As such, endurance is another individual feature we all uniquely posses. Endurance helps make us more than the sum of our parts.

But what is the meaning of endurance for athletes? Endurance can be defined in many ways. The popular college textbook Exercise Physiology, by Ardle, Katch, and Katch, discusses dozens of different aspects of endurance but does not define the term until page 756, and then only in more academic and less practical terms. Other sports researchers and authors define endurance as a form of survival. But you don’t want to just survive a triathlon like the Ironman; you want to embrace it, live it, and enjoy it—otherwise, why are you participating? One unique feature of endurance that differentiates it from true sprinting speed is effort: endurance is performed at sub-maximal exertion while sprinters perform at all-out, maximal effort.

Endurance has such a wide range of physical, chemical, and mental functions that I propose several important definitions, specifically for those athletes who engage in training for events lasting more than a few minutes:

• Endurance is our personal human performance; we use it to reach our athletic potential. As individuals, each of us defines our endurance differently—to run a 10K race, swim a mile, or bike a century. Driven by the urge to compete at the highest levels, many endurance athletes express themselves by racing professionally. Riding a bike for three consecutive weeks in the Tour de France, or going strong for eight or sub-nine hours in the lava steam bath known as the Ironman Hawaii, require superb mental and physical conditioning.

• Endurance provides the physical, chemical, and mental tools to enable us to continually power the body over relatively long distances while maintaining higher speeds at sub-maximum effort.

• Endurance is an expression of the body’s aerobic system. This key system, discussed below and throughout this book, includes aerobic muscle fibers that burn fat for energy, the nerves and blood vessels associated with the muscles, and all the support mechanisms to put them in action, including the heart and lungs. Properly training the aerobic system can allow a runner to cover five miles in forty-five minutes at a heart rate of 150, then progress to performing the same distance a month later at forty-three minutes. Or, the cyclist who can ride a flat ten-mile course averaging a steady fifteen miles per hour at a heart rate of 140, with proper endurance training can now ride the same course averaging nine miles per hour at the same heart rate. This feature of endurance is what I call aerobic speed, and is discussed in the coming chapters.

• Endurance is our ability to carry on our athleticism successfully without sacrificing our health. While much of our life, consciously or not, is dedicated to training for more endurance—and for most athletes this includes competition—there’s usually much more to do in the course of our long day. Most of us also have other daily chores—career, yard work, family, social activities, and other events that take our time and energy. Endurance sports are not separate from these other activities; balancing everything in our life is vital to building and maintaining the endurance we’ll use for training and competition.

We obtain endurance by first developing our slow-moving parts, so to speak. Our aerobic system contains slow-twitch muscles that burn fat for energy. Training these relatively slow muscles is the first step to building greater endurance, including aerobic speed, an important component of endurance. Initially, these muscles will move us at relatively slow paces. But as the body can more readily convert fat to energy, aerobic muscle function improves, enabling our endurance to build.

Another important aspect of endurance, and one that differentiates it from all-out speed, is aging. Endurance can persist for many years. Instead, too many athletes lose endurance with age—not always for lack of training, but for lack of proper training, and lack of health. Many endurance athletes can continually improve well into their forties and fifties. Master athletes often outrace younger athletes, despite having a lower maximum oxygen uptake (VO2max). But improvement over time also means that athletes who begin serious training relatively late, such as in their thirties or forties, can perform their best even in their fifties and sixties. And, athletes beyond age sixty and seventy can still achieve remarkable feats, and sometimes still outrace some twenty- and thirty-year-olds.

Aerobic Speed

One of the best ways athletes can measure their endurance is by regularly testing their aerobic speed. Since endurance is the ability to perform more work with the same or less effort, speed—as minutes per mile, miles per hour, laps per time period, and so on—can be used to keep track of progress. This is done with a heart-rate monitor, testing a sub-maximum effort, such as 75 percent of maximum, during running, cycling, or another activity over a given distance and time.

This is important not only to objectively measure progress in building better endurance, but if this progress is halted, or even reversed, due to some physical, chemical, or mental imbalance, you’ll be informed of the problem by a slowing of your pace—often long before you even feel symptoms of any imbalance. This evaluation, the maximum aerobic function test, discussed later, is best performed regularly with the results posted in your training log or calendar.

Traditional tests that supposedly measure endurance include maximum oxygen uptake (VO2max). This test measures oxygen and carbon dioxide, heart rate, respiratory rate, and other factors while an athlete runs on a treadmill or rides on a stationary apparatus. While this test has been the rage for years in the endurance world, it’s not a practical application for most athletes, and is not a good measure of endurance performance. Endurance can vary greatly among those with the same VO2max, as many athletes can outperform those with higher VO2max levels. A better evaluation of endurance, similarly performed, is the measurement of respiratory quotient as described below, which evaluates the percentage of fat and sugar burning at specific heart rates.

Endurance athletes include triathletes, runners, cyclists, mountain bikers, swimmers, ultramarathoners, skaters, and cross-country skiers. But others not usually thought of as endurance athletes must possess endurance ability or they will succumb to injury and short athletic life spans. These include basketball, hockey, football, soccer, and baseball players, those involved in racquet sports, and even racecar drivers. I do not necessarily include track-and-field sprinters, downhill skiers, competitive weight lifters, and others in this category of endurance athletes. However, they have many similar needs and can benefit greatly by following techniques and philosophies described in this book. For example, developing endurance can improve circulation to and from sprint muscle fibers, making them more effective. In addition, sprinters, jumpers, and other track and field athletes often must endure relatively long periods during competition, spending hours or even days waiting to complete their final events. Improved endurance can help prevent a loss of fitness during these periods between events.

Regardless of age, sport, or gender, virtually all aspects of our body and brain contribute to create optimal endurance. This idea can best be understood if we view endurance as an equilateral triangle.

The Endurance Triangle: The Big Picture

Although the word holistic has been overused, abused, and misunderstood for decades, it remains an appropriate term to use when one is referring to endurance. The true holistic approach to developing more endurance is one in which all aspects of the athlete are considered—these are the triad of structural, chemical, and mental fitness and health.

The holistic approach can be represented as an equilateral triangle. Each equal side represents one important aspect of the athlete: the body’s structural, its chemical, or mental and emotional state. While this concept is a simple illustration, it does not convey the complex interrelationships that exist throughout the body. For example, the muscles—a dominant part of our body’s structure—won’t power us through a workout without significant chemical activity to generate energy. And, our hormones, key aspects of our body’s chemistry that help guide our training development, are produced in the physical glands stimulated by chemical reactions. The mental and emotional components of sport—in fact, all our thoughts—are produced by chemical reactions within the structure of our brain.

Structure

This side of the triangle represents all the physical, structural, and mechanical aspects of endurance. The most obvious ones are the muscles, which promote body movement for long periods without fatigue, and support the activities of ligaments, tendons, joints, and bones throughout the body, helping to prevent them from damaging wear and tear. All the muscles are part of a body-wide kinematic chain, with virtually all these structural parts very much dependent upon one another. And, these muscles rely on the bones—in fact, our entire skeleton—for their attachment and to help leverage movement; at the same time, the muscles hold up our skeleton. The bony arches in the foot enable us to run because of the muscles that support these arches. And the physical equilibrium of the bony pelvis, itself dependent upon good muscle balance, has an indirect but significant impact on neck and shoulder movements.

The structure of the brain and all the interconnecting cells (such as neurons) that ultimately tell each muscle fiber when to contract and relax are vital to endurance. Without body chemistry, however, providing fats for use as energy, optimal endurance won’t develop. Moreover, if we try to develop endurance only through training our body structure—working the muscles during training—without considering the importance of body chemistry, we won’t reach our athletic potential.

Chemistry

The body is full of complex biochemical reactions taking place from moment to moment even at rest. These are as important as our structure for optimal endurance. These chemical activities have specific effects on other aspects of our body chemistry and on our structural and mental state. For example, the wide-ranging effects of many of the body’s hormones, including testosterone and growth hormone, influence our training. The reverse is also true, as these hormones are also influenced by our physical training. These actions control physical muscle development, the chemical reactions that supply energy, and the body’s natural anti-inflammatory chemicals, which promote recovery. These changes also influence our mental state.

Consuming different types of foods can also produce various effects on the body, which influences endurance. This takes place in the brain, muscles, intestines, and other areas. For example, a meal of highly refined carbohydrates, such as pasta, pancakes, or cereal, before training or competition can have an adverse effect on the use of fats for energy and endurance. Or, going on a diet to lose weight can result in structural changes in muscles that can cause an injury or a stress fracture in a bone. Caffeine and other popular drugs, such as NSAIDs (non-sterosidal anti-inflammatory drugs), affect the body in ways that can help or hurt endurance, too. Even the brain’s delicate chemistry can influence our muscle function, hormones, and our thought processes through the balance of chemical messengers called neurotransmitters.

Mental and Emotional

This side of the triangle incorporates our behavior through the activities of the physical and chemical brain. The mental state is also called cognition, and includes our sensations, perceptions, learning, concept formation, and decision-making. These are all important features of great endurance. We must sense our body and its relationship to the environment—such as feeling the ground with our feet as we run instead of blocking that sense with over-supported training shoes. We also sense the water as we swim, and, if we are sensitive enough, how our muscles, joints, and brain respond to training and competition.

The emotional state includes important factors such as pain, moods of anxiety or depression, and motivation to improve our natural endurance. Both our emotional and mental states can produce significant stress, if we allow it, through improper control of our structural and chemical body; this can contribute to poor performance, physical injury, and even overtraining.

The process of educating ourselves about endurance, and how training, diet, and other key features of fitness and health affect endurance is another important example of the mental-emotional side of the triangle. Education is probably the reason you’re reading this book. In many cases, reeducation is what takes place, as our society has unhealthy misunderstandings about sport. Many young people think that playing hurt is cool because of what they see and hear on television and radio. Many athletes believe that pushing themselves beyond the limit—the myth of giving 110 percent—is necessary for great endurance. Ad campaigns with unreal and unhealthy images are thrown at us and our children on a daily basis, which only perpetuates attitudes and perceptions that contribute to fit but unhealthy athletes. Without an overall balance of fitness and health, our endurance will be less than adequate.

Fitness and Health

The real lesson from my 1980 New York City Marathon experience was not one of proving health, but rather that I became fit enough to run 26.2 miles. While the terms fitness and health are often used interchangeably, they are actually two different, but mutually dependent, states.

Aerobic and Anaerobic

Two of the most important terms used in endurance sports are aerobic and anaerobic. These will be referred to often throughout this book, not only as they relate to training but also in terms of how they are affected by diet, stress and other factors.

Take a snapshot of the body’s metabolism, and the most obvious feature is oxygen. As everyone knows, oxygen is essential for energy production. But not all energy is obtained with the help of oxygen. When oxygen is used to generate energy, it is called aerobic, and when the body derives energy without using oxygen it is termed anaerobic. But these common academic definitions are not very practical. Instead, a more relevant way to define aerobic and anaerobic is by the prominent fuels they use to produce energy: fat and sugar, respectively. Let’s define each as follows:

• Aerobic: the ability of the body to use more fat and less sugar (glucose) for energy.

• Anaerobic: the ability of the body to use more sugar and less fat for energy.

The chemical generation of energy from fat and sugar occurs in the aerobic and anaerobic muscle fibers, which are important components of virtually all skeletal muscles in humans.

Note: Our body contains three kinds of muscles. Skeletal muscles are used for physical activity, and bulge when contracted; smooth muscle is contained in our intestine and blood vessels, and regulates the size of the passageways; and cardiac muscle is found in the heart, used for its beating. In this book, most of the time I will simply refer to skeletal muscle fibers as aerobic or anaerobic muscles.

Aerobic and anaerobic muscles perform a variety of activities in addition to generating movement. I will sometimes refer to these collectively as the aerobic system and the anaerobic system.

The Aerobic System

The conversion of fat to energy—fat burning—takes place in the aerobic muscles (these are sometimes called slow-twitch or red muscle fibers). Humans are well endowed with these muscles and they are the ones depended upon during activity of longer duration—they can function well for many hours and even days in a well-trained athlete. Aerobic muscles have other important functions too. Three important ones include:

• Physical support for our bones and joints. They help prevent and correct mechanical imbalances that cause injuries.

• Circulation. Literally miles of blood vessels help bring much-needed, nutrient-rich blood to the muscles, bringing oxygen, vitamins, minerals, hormones, and so forth, and removing other products such as lactate and carbon dioxide.

• Immune function. This helps our body’s natural defense control excess free radicals to prevent and recover from illness, and help regulate inflammation.

The Anaerobic System

Sugar (glucose) is converted to energy in the anaerobic muscles. These are sometimes called fast-twitch or white muscle fibers. They are used for short-term power (such as weight lifting) and sprint speed (such as an all-out 100 meter race). These attributes are used very little in endurance sports. Anaerobic energy is also very limited—relying only on this system won’t even allow a 5K race to be completed.

THE FULL SPECTRUM OF ENDURANCE

Good overall health requires proper balancing of the nervous, muscular, skeletal, circulatory, digestive, lymphatic, hormonal, and all other systems. With this balance comes optimal health and the reduction or loss of common signs and symptoms—complaints that many athletes have, which are often considered normal in the course of training and competition but, in fact, are not. Fatigue, injury, allergies and asthma, frequent colds, and other complaints indicate an imbalance of health, often due to neglecting health and pushing fitness. These aspects of health are also the very systems that provide the activities to build fitness. Athletes who are fit but unhealthy not only have problems on various physical, chemical, and mental levels, but are unable to reach their athletic potential.

Both states of fitness and health should be balanced with each other. Injuries, sickness, fatigue, and so on indicate an imbalance between fitness and health. While these problems are common, especially physical injuries, they are not normal in endurance sports the way they are in contact events such as football or hockey. It is unfortunate that most athletes are willing, consciously or not, to sacrifice health for greater fitness.

We don’t normally use only aerobic or anaerobic—or only fat or sugar—during training and competition. For example, the anaerobic system only has about three minutes of energy; and, to maintain fat burning for aerobic activity, sugar burning is also necessary. It’s mixture of these two fuels that provides us with optimal performance energy. When an endurance athlete fatigues in a race, it may be associated with the loss of available glucose necessary to sustain the conversion of fat to energy in the aerobic muscle fiber, or due to the inability to burn enough fat because of poor aerobic training.

Depending on your training, diet, stress regulation, and overall state of health, as much as 80 to 90 percent of total energy can be derived from fat. Unfortunately, too many athletes don’t burn sufficient amounts of fat, and because of this may never reach their athletic potential. One of the most important things you’ll learn in this book is how to increase energy needs through fat burning to generate optimal endurance. This includes improving aerobic speed—training the aerobic system to get faster.

As the aerobic system improves with proper training, fat burning increases and endurance improves too. This will be reflected in the RQ. For example, if an athlete today can run at a 150 heart rate and burn 50 percent fat and sugar, a month or two later he or she may improve so that, at the same 150 heart rate, now 60 percent of the energy comes from fat and 40 percent from sugar. Concurrent to these changes is a faster running, biking, swimming pace, or the same improvements in other activities.

In properly trained athletes I’ve seen tremendous values for fat burning. The chart to the right was compiled on triathlete Mike Pigg.

Training

The definition of training may be obvious, but I like to describe it in the form of an equation. Training is the balance of your workouts and your recovery in the form of rest. Simply put:

Training = Work + Rest

*At 155 heart rate, Mike can run at a sub-5:25 pace.

Regular physical training helps build muscles, improve neuromuscular activity (all those important connections between brain and muscles), increase oxygen uptake, improve fat burning, and other important benefits. Training involves stimulating the body with sufficient stress, but not too much, to provoke these benefits. In physiology this process is called overload. In the case of a muscle, for example, you must work it slightly harder than it is normally used to in order to rebuild and improve its function. Training involves programming your body in certain ways, especially through the work of physical activity, to perform better during competition.

Training also requires recovery, which comes in the form of rest. Sleep is the most important way for people to rest. Those who don’t rest enough risk overtraining, even if the workouts are ideal.

But work is not limited to just the sum total of your training. It also includes virtually all the physical activities you do in the course of the day, such as yard work and office chores. Throw in taking care of the kids, shopping, cleaning out the garage, and other physical activities, and you have a better idea of all the work you do in the course of a week, month, and year. These activities also require energy and muscle activity, burn fat and sugar, stimulate the nervous system, and other things just like training (although in most cases not as intense). However, these events, while not necessarily helping your training, still require recovery. In fact, they may even take away from your training. That’s because they increase the need for recovery.

Measuring Aerobic and Anaerobic Function

With proper equipment from exercise physiology labs or clinics, it’s relatively easy to measure the amount of sugar and fat the body is using at various heart rates. A gas analyzer can provide a fairly accurate percentage of these two main energy sources. The respiratory quotient (RQ) or respiratory exchange ratio (RER), measures the amount of carbon dioxide exhaled divided by the oxygen consumed. This is translated to a scale of 0.7 (hypothetically, 100 percent fat burning) to 1.0 (100 percent sugar burning). For example, a ratio of .85 indicates that about 50 percent of your energy is derived from sugar, and the other half from fat.

Generally, those who don’t rest enough don’t recover as well—from training, competition, and all other physical activity. Poor or incomplete recovery can lead to reduced development of the aerobic system, overtraining, and as a result, can prevent people from reaching their athletic potential. Recovery allows the muscles and other working parts to rebuild and prepare for the next bout of training, and it especially prepares the athlete to compete. During recovery, three activities are very important: no training, little physical activity, and sufficient sleep.

For many athletes, the solution to balancing the training equation is to either reduce the daily physical chores, reduce training (and competition), or a combination of all. For professional athletes and others with the benefit of being able to reduce daily chores, more time and energy can be focused on training (although more is not necessarily better). It often means cutting down on training to keep the equation balanced. When this happens, improved performance ultimately follows.

One of my patients, whom I will call Bob, was a good local runner who loved road racing and desperately wanted to improve. But his expanding business and growing family were demanding more time from his busy training schedule. He tried to accommodate everyone and maintain his training. He was waking up earlier in the morning to train, resulting in less sleep. He soon was complaining of fatigue that lasted all day, and eventually developed pain in his knees and lower back. In the middle of a very successful racing season, his performances quickly began to deteriorate. At this point he consulted me. The first thing I recommended for Bob was that he cut his training down by about 40 percent, since he was not able to decrease any of his other commitments. Almost immediately his energy improved and his physical problems disappeared. After about four weeks on his modified schedule, Bob ran a great race and continued racing well for the rest of the season, maintaining his reduced training schedule.

Endurance sports has existed for millions of years in its most natural form, and organized forms only quite recently, with participation in endurance events such as road running, triathlons, and cycling exploding in the past thirty years. Today’s endurance athletes, who far outnumber athletes who participate in shorter or sprint events, have been influenced more by the philosophies used to train sprinters than by distance coaches, athletes, and others. This is due, in part, to the presence of many former sprinters, for example, who began coaching in the endurance world. They began training endurance athletes much in the same way they themselves trained. As a result, endurance athletes often hold on to that tradition of sprint workouts. These include track or pool intervals, for example, to increase

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