Joel Jamieson

March 29, 2018 | Author: alex_carnall6060 | Category: Lactic Acid, Muscle, Muscle Contraction, Skeletal Muscle, Glycolysis


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Joel Jamieson: Ultimate MMA ConditioningEnergy Systems Breakdown System Aerobic Anaerobic – Lactic Anaerobic - Alactic Characteristics      Generates ATP at slowest rate of all 3 systems Is dependent on oxygen and involves the greatest number of chemical steps Fuels low intensity activity and refuels anaerobic mechanism between efforts Improving this system relies on both concentric and eccentric cardiac hypertrophy When expenditure outweighs production due to increased intensity, this is anaerobic threshold           Provides energy faster than aerobic, but only lasts about a minute More work at higher intensities produces greater concentrations of blood lactate Lactate may actually delay fatigue by “soaking up” H+ ions Lactate is also preferentially used as fuel by cardiac and tonic muscle, and the brain Lactate is blamed for soreness/fatigue because it marks transition between systems Higher accumulations of lactate actually indicate increased resistance/adaptation to anaerobic conditions Improving this system relies on improving both anaerobic lactic power and lactic capacity To improve lactic power – Shorter M.E. reps w. longer recovery = Increase enzymes & glucose uptake To improve lactic capacity – Longer reps w. shorter recovery = Increase “buffering capacity” When intensity is too high to continue metabolizing lactate with aerobic process, switch to lactic        Reliant on small amounts of ATP & PCr within muscle, can only generate for 10-12s at max intensity Will be better suited for repeat efforts with a capable aerobic system Produces energy most readily due to the fewest chemical steps of all 3 systems Is least trainable of all 3 systems, largely influenced by genetic and physiological predispositions Increasing volumes of rate-limiting enzyme Creatine Kinase can improve the system capacity Active rest is best between sets to augment aerobic recovery process Efficient specific fiber selection and contractile (contraction/relaxation) mechanisms improve capacity Aerob ic Lactic A lacti c Transition between these phases is simply a function of the intensity dictating whether or not they are capable of maintaining adequate energy production through either power (intensity) or capacity (duration.) The entire concept of “energy systems” revolves around maintaining homeostasis, and the system of majority contribution is in effort to make energy available based on the present conditions, namely intensity and duration. The central governor model of fatigue is a theory which states that rather than lack of oxygen or accumulation of metabolic byproducts, it is the brain and central nervous system which carefully monitors and moderates output to prevent damage to the working muscle fibers. Components of Aerobic Energy Production Aerobic Power Oxygen Supply Cardiac Output Peripheral Vascular Network Respiratory System Aerobic Power & Aerobic Capacity Oxygen Utilization Number and Size of Slow/Fast Fibers Oxidative Abilities of Fast Twitch Fibers Aerobic Enzymes Aerobic Capacity Substrate Availability Efficiency of Aerobic Energy Production Substrate Storage Capacity Hormonal Regulation Anaerobic Lactic Adaptations Anaerobic Lactic Power Amount of Glycolytic Muscle Tissue Number of Glycolytic Enzymes Nervous System Development Anaerobic Lactic Capacity Availability of Energy Substrates pH Buffering Ability Rate of Clearance of Byproducts (Metabolizing lactate for further use) Anaerobic Alactic Adaptations Rate of Alactic Energy Production Alactic Enzymes Capacity of Alactic Energy Production Phosphocreatine Stores External Power Output Muscular Contractility .Components of Conditioning Rate of Energy Production (Power) Central Governing Control (Power Regulation) Energy Production Energy Utilization Duration of Energy Production (Capacity) Total Potential of Energy Production (Biological Power) Efficiency of Energy Expenditure (Skill/Technique ) Neuromuscular Contractility (Mechanical) Conditioning as a whole is essentially tuning energy production to effectively and efficiently serve energy utilization as dictated by the demands of duration and intensity by the activity in question. Biking. Lower Body: Squat . Improves oxygen supply at higher intensities and improves the power endurance of the cardiac muscle. Offers high intensity and volume. Recruits highest threshold motor units using low intensity plyos and improves their endurance.Aerobic System Methods Method Purpose Cardiac Output Cardiac Power Intervals Tempo High Intensity Continuous Training (HICT) Threshold Training High Resistance Intervals (HRI) Aerobic Plyometrics Improves oxygen supply by increasing how effectively the heart can deliver oxgen and develop peripheral vascular network. This delays the point at which these processes take over. Recruits highest threshold motor units and increases oxidative abilities of the fibers by supplying them with constant oxygen. Increases left ventricular cavity volume. Mechanism Stimulates eccentric cardiac hypertrophy through volume overload of cardiac fibers causing them to stretch. 5-10min/Set 1-3Sets/Ex. Raises the anaerobic threshold. Upper Body: Explosive Pushups. Increases maximum rate of ATP generation in aerobic system (increase aerobic power. Spin Bikes. Resistance  Low Speed  10-20min/Set  1-2 Sets/Day  1-2x/Week  +/. along with corresponding increase in mitochondria. Increase work. Versaclimber. Uphill Sprint. MB Rebounding. Stimulates increase in contractile strength – concentric – cardiac hypertrophy. decrease rest for Exercises Low intensity activity: Jogging. Swimming. Stimulates hypertrophy of the slow twitch fibers by causing localized hypoxia to working muscles through controlled tempo. All is fine as long as heart rate is in the correct range Sprinting or high intensity “sport-specific” exercise which maximally elevates the heart rate Any major compound movement Spin Bike. Sled Drags. Larger slow twitch fibers contribute to aerobic and anaerobic endurance as well as static strength.5bpm ANT  Stay in Range  3-10min/Rep  2-5 rep/Wkout  1-2x/Week            HR below ANT Max Intensity Rest to 130140bpm 10-12s/Rep 15-20rep/Wkout HR below ANT Mod. High Resistance Cardio Machines. Improving aerobic abilities of the fast twitch fibers means high power can be maintained longer.) Improving aerobic abilities of fast twitch fibers means high power can be maintained longer. Stimulates greater oxygen utilization and results in increased endurance of fast twitch fibers. Improves fast twitch Guidelines  130-150bpm  Below ANT  30-90minute sessions  Increase volume for progression  1-3x/week total  Maximal HR each rep  Rest 2-5min or to 120-130bpm  4-12 Reps/Session  1-2x/Week  2s Ecc/Conc. Gradient imposed resistance Any “cardio” activity including specific drills. and power at the anaerobic threshold. Jumping Rope.  No Pausing  3-5 Sets  8-10 Reps/Set  3-4 Exercises/Day  Max. Intensity 10-30s Rest int. Lower Body: Double leg bound.  60-90s/Circuit.  Goal: Complete Fatigue  Power  20-30s/Ex. Split Squat Jumps w.Explosive Repeat How quickly fast twitch fibers can recover between explosive bursts. Purpose Mechanism Stimulates increase in the enzymes involved in anaerobic glycolysis and shifts metabolism of working muscles to rely more on anaerobic vs. Anything goes.  Capacity  30-60s/Ex. Stimulates increase in the buffering mechanisms involved in allowing anaerobic glycolysis to continue. Also increases glucose storage and utilization potential. KB or BB Upper Body: Explosive Pushups or Bench Press Lactic System Methods Method Lactic Power Intervals Lactic Capacity Intervals Circuit Training Lactic power output during prolonged high intensity periods. 8-10min active rest btwn series 1-2 Series 6-10 Set/Ex. . Jumps.  1-2min/Circuit  60-90s btwn Ex. aerobic metabolism. Lower Body: Squat Jumps & Split Squat Jumps w. 1-3 Ex./wkout.  8-10min before changing circuits./Wkout 1-2x/Week.  1-3 series of 610 sets per exercise  1-3 ex.      prog.  1-3min btwn Circuits  Repeat Circuit 24 times.  6-8min btwn circuits.  90-120s/Rep  2-4 Sets of 3  Incomplete rest intervals  1-2min btwn reps  4-6min active rest btwn sets. aerobic abilities and repetitive power outputs by developing lactate oxidation in slow twitch fibers. Increases enzymes involved in lactic ATP Guidelines  Max intensity/Speed each rep  20-40s per Rep  2-4 sets of 3  8-15min rest btwn series. Can improve lactic power and capacity of many different muscle groups in a time effective manner.  Increase work. decrease rest each week for prog. Exercises Anything from sprints to specific sport drills as long as it’s done at max speed and intensity. Stimulates increase in Lactic Power or Capacity. Produces very rapid rate of ATP turnover and high levels of blood lactate when large muscle groups are used. Ability to sustain anaerobic energy production for extended periods of time. Improves maximum capacity of the alactic system by increasing the amount of stored phosphocreatine. Mechanism Improves maximum rate of ATP regeneration by alactic system by increasing amount of enzymes involved in production. Increase alactic power output and results in high level of hormonal production./Wkout. Pushups etc. DB Bench. Mod./wkout  1-2x/wk  3-4 heavy sets of 3-5 reps and follow with 3-4 sets of 8-10  2-3 ex.Lactic Explosive Repeat Ability to maintain repetitive explosiveness. Guidelines  2-5min btwn reps or recover to 120bpm or lower  7-10s/Rep  5-6Reps/Set  1-3x/Wk. Press.E./wkout  2-5min btwn M. RDL. Speed 10sPauses Sets of 3-10min KB or BB Upper Body: Exp. Sh.  2-3 exercises  1-2x/wk  2-3 sets  2-3 ME Reps Exercises Any repetitive explosive exercise. Same as for power intervals Major Compounds Major Compounds . Improves strength of both fast and slow twitch fiber by increasing nervous system function and size of slow twitch fibers. 1-2x/Wk. such as jump squats. exp. production as well as buffering mechanisms to improve lactic capacity. Pushups or Bench Press DB Squat. sprinting. Improves maximum neuromuscular recruitment and can play a role in improving contractility.      Active rest 810min btwn series Work Intervals of 12-40s Rest intervals of 10-30s 1-3Ex. Lat PD Etc. Alactic System Methods Method Alactic Power Intervals Alactic Capacity Intervals Max Effort Method Strength-Aerobic Purpose Explosive Bursts and ability to be quick and powerful Helps improve ability to maintain explosive power for extended durations.  Work interval of 10-15s  Rest interval of 20-90s  Active rest of 810min btwn series  10-12reps/set  2-3ex/series  2-5 sets  1-5 reps/set  2-5min btwn set  2-3 ex.    Static Dynamic Lactic Process leads to fatigue if toleranc is poor Increase tolerance to buildup of specific fatigue thoruhg buffering and inorganic P buildup. Fast and slow twitch fiber strength plays a key role in being able to sustain repetitive high power output.  40s btwn tempo efforts  8-10min btwn ex. bounding. Methods 3.Develop nervous systems ability to maximally recruit fibers and improve explosive ability. Volume 5. Training Type 2. Explosive Speed & Power 4. Exercsie Selection Each block should be divided into an A & B wherein 2 sessions per week in each block are concentrated loading for primary adaptation and 1 day per week devoted to maintaining peripheral or secondary adaptations. Power-Endurance *Power-Endurance is developed after each quality is independently developed. Complex Improve maximum amount of muscle recruitment as well as increase amount of alactic enzymes to improve alactic power. Order of Importance in Program Design Factors 1. General Strength 3. ME Exercises for first sets.    immediately followed by 3 x 6-8 as explosively as possible. General Endurance 2. and recommended alactic power interval exercises for second group of sets Training Sequencing Model 4 Blocks 1. Max accel. 1-2x/Wk./Wkout. Block B Block A 1 2 A Block Emphasis General Endurance General Endurance Block A Cardiac Output Tempo Method HICT Low Volume Intervals Technical Work 3 1 4 2 5 Transition General Endurance Block B Threshold Method HICT/HRI/Aerobic Plyometrics Explosive Repeat Method Cardiac Output General Strength General Strength Block A Tempo Method Max Effort Strength – Aerobic Method General Strength Block B Max Effort Complex or Shock Method 3-5 Rep Ranges 3 4 B Block Emphasis 5 . On all reps 2-3 ex. Intensity 4. Tempo Method (Moderate Volume) Keep HR +/.5-7 Rep Range Longer Rest Periods Consistent Increase in Intensity is Focal Explosive Speed & Power Block Exp. Circuits HICT. Speed/PWR Block A Explosive Repeat Method Max Effort Max Acceleration Rest-Pause Longer Rest Between Sets Exp. Shorter Rest Periods Cardiac Power Method Lacic Power/Capacity Intervals Increase Volume above Anaerobic Threshold Maximal Duration Past Fatigue .5bpm of Anaerobic Threshold Increase Power at the Anaerobic Threshold Power-Endurance Block B Longer Work. Speed/PWR Block B Complex Method Shock Method Specific Game Exercise and Speed 8-15s Sets Lighter Intensities at Game Speed Power-Endurance Block Power-Endurance Block A Threshold Training Explosive Repeat Method.
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