SportsMed_June04


28 SPORTS MEDICINE   VOL 16 NO.2   2004

Introduction

Super-compensation is the main principle in physical training
aimed at improving performance.  A breakdown process in
skeletal muscle is followed by a recovery process, resulting
in adaptation and possibly increased exercise performance.32

Exercise has a profound effect on skeletal muscle metabo-
lism resulting in net muscle protein breakdown and glycogen
depletion during exercise, followed by net protein synthesis
and, depending on nutrient availability, glycogen storage
post-exercise.  The recovery process (muscle regeneration,
glycogen and fluid restoration) is regarded as critical to suc-
cessful training and adaptation, and nutrition has been iden-
tified as a major contributor in this process.35 Increasing the
rate of recovery post-exercise, or decreasing the rate of
catabolism during exercise, could lead to speedy and effec-
tive recovery between training sessions.  An enhanced
recovery process is of particular importance to athletes who
do more than one training session per day, and/or engage in
strenuous multi-day training or competition schedules.
Macronutrients, specifically carbohydrate  (CHO) and pro-
tein, have been identified as crucial dietary components in
enhancing the recovery process.  By regulating the timing,
amount and type of these nutrients ingested, anabolism
post-exercise can be reached at an earlier stage compared
with unregulated ingestion of these nutrients.24,25,49

This article consists of two parts, focusing on the effect of
the macronutrients, individually and in combination, on
glycogen storage (Part I) and skeletal muscle repair (Part II)
post-exercise.  In both parts possible mechanisms will be
identified and conclusions drawn.  At the end of Part II one
combined set of dietary recommendations for optimal recov-

REVIEW ARTICLE  

Dietary macronutrient recommendations for optimal 
recovery post-exercise: Part I

H H Wright (MSc Dietetics, PhD Nutrition)1

A Claassen (BSc (Hons) Dietetics, BSc (Med) (Hons) Exercise Science)2

J Davidson (DSc)3

1Potchefstroom Institute of Nutrition, Faculty of Health Sciences, Northwest University, South Africa
2UCT/MRC Research Unit for Exercise Science and Sports Medicine, Faculty of Health Sciences, University of Cape Town, South Africa
3College of Education and Health Sciences, Bradley University, Peoria, Illinois, USA

CORRESPONDENCE:

H Wright
School of Physiology, Nutrition and Consumer Science
North-West University
Private Bag X6001
Potchefstroom, 2531
Tel: 018-299 2482
Fax: 018-299 2464
E-mail: vgehhw@puk.ac.za

Abstract
Prolonged, strenuous exercise results in muscle glycogen
depletion.  Recovery of these stores prior to the next train-
ing session or competition is crucial to optimise exercise
performance.  Nutrition plays an important role during the
post-exercise recovery period when processes such as
muscle regeneration, glycogen and fluid restoration take
place.  By manipulating the timing, type and frequency of
food intake the rate of recovery can be enhanced, which
is of particular importance to athletes performing multiple
training or competition sessions within a day, or on a day-
to-day basis and recovery time is limited.  Restoration of
muscle glycogen stores is especially important for ath-
letes participating in prolonged exercise, since depleted
glycogen stores are associated with impaired exercise
performance.  Key factors affecting muscle glycogen stor-
age are carbohydrate (CHO) availability and an increased
insulin concentration, both of which are influenced by
amount and timing of CHO intake, type of CHO ingested,
the ratio of CHO to protein ingested, and the fat content of
a food item or meal.  To maximise the rate of muscle
glycogen restoration during a short (< 6-hour) recovery
period, 1 - 1.5 g moderate to high glycaemic index
CHO/kg body weight (BW) immediately post-exercise, fol-
lowed by 0.8 - 1.5 g moderate to high glycaemic index
CHO/kg BW/hour (divided in smaller doses every 15 - 60
minutes) for 3 - 4 hours should be ingested.  With a longer
recovery period (≥ 6 hours) muscle glycogen storage is

independent of type of CHO ingested but a total of 7 - 10 g
CHO/kg BW should be taken in within a 24-hour period.
Combining protein with an adequate amount of CHO (> 1
g/kg BW/hour) has no added advantage in terms of
enhanced rate of glycogen storage, but can be of practical
importance.  Additionally, this combination may be benefi-
cial since CHO and amino acid availability are important
for muscle repair during the recovery period, as will be
discussed in detail in Part II of this article.



SPORTS MEDICINE    VOL 16 NO.2   2004 29

ery of glycogen stores and skeletal muscle repair post-exer-
cise is provided.  

Glycogen storage 

Glycogen, specifically muscle glycogen, is the predominant
fuel source during exercise of moderate to high intensity (>
60% maximal oxygen uptake (VO2max).

45 During prolonged
exercise, glycogen stores become depleted and blood glu-
cose concentrations may start to decline, a situation which is
often associated with a decrease in CHO oxidation and
impaired exercise performance.4;5;13;22 Hence, efficient recov-
ery of glycogen stores (in the liver and muscles) in the post-
exercise period has been identified as an important strategy
to enhance subsequent exercise performance.   Restoration
of these stores is dependent on glucose supply originating
from dietary CHO.  Restoration of liver glycogen stores is
important for optimal maintenance of blood glucose concen-
trations, which serve as the predominant fuel source to the
brain and central nervous system,38 as well as to the working
muscles when muscle glycogen becomes depleted.4,19,55

However, restoration of muscle glycogen in the post-exercise
period takes precedence over liver glycogen restoration,
which, even in the absence of dietary CHO supply, can occur
at a low rate (~ 1 - 2 mmol/kg wet weight (ww)/hour), with
some of the substrate being provided through gluconeogen-
esis.3 Therefore, Part I of this article focuses on aspects
increasing the rate of muscle glycogen recovery specifically.  

Dietary factors affecting muscle glycogen storage

The key dietary factors that can enhance the rate of muscle
glycogen synthesis include: increased CHO (glucose) avail-
ability;17 an elevated insulin concentration;21 and the combi-
nation of CHO and protein or amino acids to increase the
insulinotrophic effect and provide substrate for glycogen and
muscle protein regeneration.26

Non-dietary factors that may augment the rate of glyco-
gen synthesis (for detailed review see Jentjens and
Jeukendrup30) include glycogen synthase activity (increased
by both muscle contraction and insulin); glucose transport
protein-4 (GLUT-4) availability and translocation within the
muscle cell (increased by muscle contraction and insulin
concentrations); training status (training increases insulin
signalling and sensitivity, GLUT-4 content, and blood flow);
degree of muscle glycogen depletion (glycogen depletion
may increase GLUT-4 availability and glycogen synthase
activity, thereby increasing the rate of muscle glycogen
restoration).30

CHO availability:  Amount and timing of CHO ingestion

It has been established that post-exercise glycogen synthe-
sis takes place in a biphasic manner, with a rapid, insulin-
independent phase lasting between 30 and 60 minutes, and
a slow, insulin-dependent phase, which, depending on CHO
availability and high insulin levels, can persist for several
hours.42,43 The rapid phase only occurs when post-exercise
muscle glycogen concentrations are below 30 - 35 mmol/kg
ww43 and CHO is provided immediately post-exercise.28

Hence, of the abovementioned dietary factors, CHO avail-
ability remains the key factor affecting both phases of post-
exercise glycogen synthesis and rate of recovery.  

Several studies have demonstrated very low rates of mus-
cle glycogen synthesis when no CHO was ingested or when
CHO intake was delayed (> 2 hours) compared with immedi-
ate CHO ingestion post-exercise.28,48,51 The mechanism
behind an increased rate of glycogen synthesis with immedi-
ate post-exercise CHO ingestion might be related to an
increased glycogen synthase activity (for review see Nielsen
and Richter37) and GLUT-4 availability immediately following
exercise.36 However, in the absence of CHO ingestion, these
exercise-induced increases in glycogen synthase and GLUT-
4 availability (and hence the potential for glucose transport)
may decline rapidly.12,23

When considering the ideal amount of CHO to be ingest-
ed, Blom et al.3 demonstrated an increase in muscle glyco-
gen synthesis rate of ~ 150% when post-exercise CHO
intake was increased from 0.18 to 0.35 g/kg body weight
(BW)/hour (provided at 2-hourly intervals post-exercise), but
no further increase when CHO intake was increased to 0.7
g/kg BW/hour.  Similarly, Ivy et al.29 found no difference in
muscle glycogen synthesis rate between the ingestion of
0.75 vs. 1.5 g CHO/kg BW/hour (provided at 2-hourly inter-
vals) over a 4-hour period post-exercise.  These two stud-
ies3,29 suggested a 'glycogen synthesis threshold' and an
upper limit for CHO ingestion of between ~ 0.35 - 0.7 g/kg
BW/hour.  However, several more recent studies42,48,51,53 have
demonstrated glycogen synthesis rates beyond those report-
ed in these two studies (~ 145 - 170% higher) when 1 - 1.7
g CHO/kg BW/hour was ingested, hence providing evidence
against the existence of such an upper limit or threshold.  

For example, Van Loon et al.53 demonstrated a ~ 200%
increase in the rate of glycogen synthesis when CHO intake
was increased from 0.8 to 1.2 g/kg BW/hour (~ 145% higher
than Blom et al.3 and Ivy et al.29).  Several others have report-
ed even higher rates of muscle glycogen synthesis (~ 170%
higher) when 1 - 1.7 g CHO/kg BW/hour was ingested at 15
- 60-minute intervals during a 3 - 4-hour recovery period.31,42,53

In these studies, the CHO beverages were provided at 15 -
60-minute intervals post-exercise, as opposed to 2-hourly
intervals as in the studies where no difference in rates of
muscle glycogen synthesis were found.3,29 Additionally, Ivy et
al.29 reported that if beverages are provided on a 2-hourly
basis, then a CHO intake of > 0.5 g CHO/kg BW/hour is
needed in order to maximise glycogen synthesis post-exer-
cise.

Collectively taken, these results may highlight the possi-
bility that frequent CHO ingestion in the early hours post-
exercise may be better able to increase and maintain
glucose availability and insulin concentrations, as opposed
to when provided on a 2-hourly basis.  

Although the exact amount of CHO to maximise post-
exercise glycogen recovery has not been fully established
yet, the abovementioned evidence suggests that optimal
muscle glycogen synthesis will be achieved by the ingestion
of 1 - 1.5 g CHO/kg BW immediately after exercise, followed
by 0.8 - 1.5 g CHO/kg BW/hour (ideally divided into small
doses every 15 - 60 minutes) for at least 3 - 4 hours there-
after, aiming for a total of 7 - 10 g CHO/kg BW over a 24-hour
period.   



Type of CHO ingested

The type of CHO ingested plays an important role in the rate
of glycogen synthesis as it affects the rate of digestion and
absorption of the CHO, and ultimately glucose availability.  

As mentioned earlier, glucose availability is an important
determinant of glycogen synthesis.  Furthermore, insulin
stimulates glycogen synthase,2 which is considered the rate-
limiting enzyme in the glycogen synthetic pathway,20 as well
as GLUT-4 translocation which facilitates glucose uptake.21

High glycaemic index (GI) CHO-rich foods elicit a high glu-
cose and insulin response within the first 2 hours after inges-
tion.6 Thus, using high GI CHO foods during the early
recovery period should increase the rate of glycogen synthe-
sis and thereby achieve a higher glycogen concentration
sooner, compared with a low GI CHO food.

Blom and co-workers3 found that the ingestion of glucose
(high GI) and sucrose (moderate GI) feedings after pro-
longed exercise increased the rate of glycogen synthesis sig-
nificantly higher at 6 hours post-exercise compared with
fructose (low GI) feeding.  Surprisingly, sucrose (moderate
GI), which contains equimolar amounts of fructose (low GI)
and glucose (high GI), resulted in similar rates of glycogen
synthesis and muscle glycogen levels than a similar amount
of glucose (high GI).  A possible explanation for this result
may be that fructose inhibits post-exercise hepatic glucose
uptake, thereby increasing the amount of glucose available
for muscle glycogen synthesis.3

Interestingly, Piehl Aulin and co-workers42 found that a
post-exercise CHO drink containing glucose polymers (high
GI) resulted in a significantly higher rate  of glycogen syn-
thesis 4 hours post-exercise compared with an isocaloric glu-
cose-containing drink (high GI) (50 vs. 30 mmol/kg dry
weight/hour).  It was suggested that the lower osmolality of
the glucose polymer drink versus the glucose drink (84 vs.
350 mOsm/l) led to greater gastric emptying rates and a
faster delivery of substrate to muscle.  Although there was no
difference in insulin and glucose response, there could have
been a greater non-insulin dependent uptake of glucose in
the muscle during the early (30 - 60 minutes) post-exercise
period.  This hypothesis merits further investigation.

During a longer recovery period (> 6 hours) timing and
type of CHO ingested seems to be of lesser importance than
the amount ingested.9,17,33,40 After strenuous glycogen-deplet-
ing exercise, the ingestion of 7 - 10 g CHO/kg BW/day will be
sufficient to restore glycogen stores over a 24 - 48-hour peri-
od.9,10,33 For athletes participating in less strenuous exercise
lasting 60 - 120 minutes/day, the ingestion of 6 - 8 g CHO/kg
BW/day would be sufficient to restore glycogen stores within
this time frame.7

There are limited  data available on the role of the GI dur-
ing longer recovery periods, probably due to practical diffi-
culties, but also due to evidence9,15,18 suggesting that amount
of CHO ingested is more important than the type (GI) of CHO
itself during these periods.  

In summary, for athletes who train/compete twice (or
more) a day, and/or have a strenuous day-to-day training or
competition schedule with limited recovery time, it is recom-
mended to opt for CHO-rich foods of moderate to high GI
within the first 6 hours post-exercise.  After 6 hours, foods
with low GI can be included, provided that the overall CHO

requirement (~ 7 - 10 g CHO/kg BW within 24 hours) is met.
For athletes who have 6 or more hours to recover before a
subsequent strenuous exercise bout, the type of CHO (low or
high GI) is of lesser importance, provided that the amount of
CHO to be ingested within a 24-hour period be sufficient 
(~ 6 - 8 g CHO/kg BW per 24 hours for moderate-intensity
exercise or 7 - 10 g CHO/kg BW per 24 hours for more stren-
uous/prolonged exercise).

Effect of combining CHO and protein on muscle glyco-
gen storage

Though insulin secretion is mainly determined by CHO
ingestion and blood glucose concentration, it has been
shown that certain amino acids51-54 and/or protein pep-
tides52,54,57 have a synergistic effect on insulin concentration
when combined with CHO.   As mentioned before, insulin
stimulates glycogen synthase and muscle glucose uptake,
thus enhanced insulin release post-exercise may therefore
increase the rate of muscle glycogen synthesis.31,51-53,57

Zawadski and co-workers57 were the first researchers to
find that the addition of whey protein to a CHO supplement
(112 g CHO + 40.7 g protein/serving) taken immediately and
2 hours after an hour of glycogen-depleting exercise
increased the rate of glycogen synthesis during a 4-hour
recovery period compared with a CHO-only supplement 
(112 g CHO/serving).  However, the increased rate of glyco-
gen synthesis could have been due to the added energy,
since the two drinks were not isocaloric.  Since then, only
one other study27 found that muscle glycogen concentrations
were higher (4 hours post-exercise) in a CHO supplement
with added protein (80 g CHO + 28 g protein + 6 g fat/serv-
ing) compared with an isocaloric CHO-only (108 g CHO + 
6 g fat/serving) supplement given immediately and 2 hours
after a 2.5 hour glycogen-depleting cycling protocol.
Unfortunately, the rate of glycogen synthesis was not reported. 

Subsequently, Van Loon et al.53 provided beverages at 30-
minute intervals up to 270 minutes post-exercise and com-
pared the ingestion of 0.8 g CHO/kg BW/hour with 0.8 g
CHO/kg BW/hour plus 0.4 g/kg BW/hour of wheat protein
hydrolysate plus leucine and phenylalanine (proven to be
highly insulinotrophic),54 and with 1.2 g CHO/kg BW/hour.
Adding the protein mixture (0.4 g/kg BW/hour) to the CHO
beverage (0.8 g/kg BW/hour) increased the plasma insulin
response and muscle glycogen synthesis rate by ~ 113%
compared with the ingestion of 0.8 g CHO/kg BW/hour only.
However, increasing the CHO content by 0.4 g CHO/kg
BW/hour to 1.2 g/kg BW/hour also resulted in a faster rate of
muscle glycogen synthesis of ~ 170% compared with inges-
tion of 0.8 g CHO/kg BW/hour.53 This study clearly demon-
strated that maximal rates of muscle glycogen synthesis are
not reached when 0.8 g CHO/kg BW/hour is ingested, and
that this rate can be increased by the addition of 0.4 g/kg
BW/hour of either protein or more CHO.  The question then
arose whether the addition of protein/amino acids to a larger
CHO beverage (> 1 g CHO/kg BW/hour) would further
increase the rate of muscle glycogen synthesis.  In answer to
this question, Jentjens et al.31 demonstrated that combining
0.4 g/kg BW/hour of an insulinotrophic protein-amino acid
mixture with a CHO beverage containing 1.2 g CHO/kg
BW/hour, given at 30-minute intervals post-exercise, does
not increase the rate of muscle glycogen further, despite

30 SPORTS MEDICINE   VOL 16 NO.2   2004



SPORTS MEDICINE    VOL 16 NO.2   2004 31

much higher insulin concentrations.  

The majority of studies11,31,46,48,50-53 investigating the effect of
combining protein and/or amino acid-mixtures with a CHO
supplement have not shown an enhanced rate of glycogen
synthesis when the  amount of CHO ingested was above 1
g/kg BW/hour.  Despite higher insulin concentrations, the
rate of muscle glycogenesis in these studies was unaffected
by the addition of protein/amino acids compared with an
isocaloric CHO beverage.  Furthermore, Tarnopolsky and co-
workers48 found significantly higher glycogen concentrations
(4 hours post-exercise) after ingesting a CHO-only (1 g
CHO/kg BW/serving) compared with an isocaloric CHO-pro-
tein (0.75 g CHO + 0.1 g protein + 0.02 g fat/kg BW/serving)
supplement after a glycogen-depleting exercise protocol.
These results are supported Wojcik and co-workers,56 and
may suggest that insulin is not the rate-limiting factor for
muscle glycogen synthesis when the overall rate of CHO
intake is high (> 1 g CHO/kg BW/hour).  

Though the rate of glycogen synthesis might not be
enhanced by adding protein and/or amino-acid mixtures to a
CHO supplement, it might be of practical importance, since
a lower volume supplement/drink can be ingested post-exer-
cise, when most athletes experience loss of appetite,34 and
still result in efficient recovery of glycogen stores.
Furthermore, adding protein to a recovery supplement/drink
might be beneficial for muscle repair post-exercise. This will
be discussed in more detail in Part II.

Effect of combining CHO, protein and fat on glycogen
storage

Co-ingestion of fat reduces the plasma glucose response
(but not insulin secretion) to both high and low GI CHO
foods, possibly due to delayed gastric emptying.14 The addi-
tion of fat and protein to a CHO meal may cause similar lev-
els of glycogen storage at 24 hours post-exercise compared
with a CHO-only diet, provided that the CHO intake is ade-
quate.8;46

Effect of type of exercise on glycogen storage

Type of exercise also has an effect on rate and amount of
muscle glycogen stored post-exercise.  The rate of glycogen
synthesis after short-term high-intensity exercise is higher
than after prolonged or resistance exercise.41 Possible fac-
tors contributing to this effect include higher peak blood glu-
cose and insulin levels post-exercise, higher levels of
glycolytic intermediates and lactate concentration in muscle
and blood, as well as greater glycogen depletion in glycogen
synthase-rich fast-twitch glycolytic muscle fibres (for review
see Pascoe and Gladden41).  Additionally, eccentric exercise
(usually part of resistance training) is associated with
reduced rates of glycogen resynthesis.16;39 Potential mecha-
nisms include competition between inflammatory cells and
muscle cells for available glucose,16 a metabolic shift towards
glycogenolysis induced by inflammatory cells,47 reduced
GLUT-4 levels,1 and an increase in calcium which could
inhibit glycogen synthase.44

Conclusions

Prolonged, strenuous exercise results in muscle glycogen
depletion.  Recovery of these stores prior to the next training
session or competition is crucial to optimise exercise perfor-
mance.  Nutrition is a major contributor to the recovery of
muscle glycogen stores and the rate at which it occurs,
which is especially important for athletes engaging in multi-
day training or competition schedules.  The rate of glycogen
storage can be increased by ingesting a sufficient amount of
CHO (> 0.8 g CHO/kg BW/hour) immediately post-exercise
at 15 - 60-minute intervals during the first 3 - 4 hours of the
recovery period.  Ingesting high GI CHO during the early
recovery period (≤ 6 hours) results in a higher rate of glyco-
gen storage than low GI CHO.  The total amount of glycogen
stored within a 24-hour period post-exercise is, however, not
dependent on the GI per se, but rather on the amount of
CHO ingested during the recovery period.  Thus, the GI only
seems to be important when there is a short recovery period
(< 6 hours) between training sessions.  Finally, combining
CHO and protein post-exercise does not seem to result in a
higher rate of glycogen storage compared with when a high
CHO-only supplement is ingested at a rate of >1 g CHO/kg
BW/hour.  This combination may, however, still be of benefit
to the muscle recovery process since CHO and amino acid
availability are important for muscle repair during the recov-
ery period, as will be discussed in detail in Part II.

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