Pseudoanemia
Michelle Burke
Julie M. Kerr
BasicsDescription
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Dilutional phenomenon in endurance athletes causing hemoglobin and hematocrit values that are lower than established limits of normal
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Plasma volume expansion by 10–20% with little change in red cell numbers (ie, oxygen-carrying capacity; red cell mass remains unchanged) (1)
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Contributing factors include:
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Exercise-induced release of aldosterone, renin, and vasopressin
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Increased size of vascular bed owing to muscle hypertrophy
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Retention of crystalloids and colloids governed by hormones
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Theoretically, this increased blood volume decreases viscosity, thereby maximizing stroke volume, cardiac output, and subsequent oxygen delivery (2).
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Hemodilution occurs over the 48 hr after every episode of endurance exercise and may persist for as long as 1 wk after discontinuing training.
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If training continues, red cell mass will catch up with plasma volume expansion over the span of few weeks, causing hemoglobin and hematocrit values to normalize (3).
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Synonym(s): Sports anemia; Athletes' pseudoanemia
Epidemiology
Incidence
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Elite athletes involved in endurance training
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Previously sedentary individuals starting an exercise program
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Athletes increasing intensity of training
DiagnosisHistory
Check exercise schedule, type of training activity, and occurrence of any symptoms.
Physical Exam
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Hemoglobin levels 13–14 g/100 mL in men and 11–12 g/100 mL in women; dose-response relationship between amount/intensity of exercise and hemoglobin drop (4)
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Elite endurance athletes have a greater degree of dilutional pseudoanemia than more moderate endurance athletes.
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Females are more likely than males to have iron-deficiency anemia with sports ± presence of pseudoanemia.
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No particular symptoms or physical findings
P.495
Diagnostic Tests & Interpretation
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Laboratory studies are performed if etiology unclear or symptoms are present.
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Normal mean corpuscular volume
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No hematuria or hemoglobinuria on urinalysis
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Normal bilirubin and haptoglobin
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Ferritin may be lower in endurance athletes owing to the same relative dilutional effect. Values often <60 µg/L, occasionally <30, but <15 = iron deficiency.
Differential Diagnosis
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Iron-deficiency anemia
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GI bleeding
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Hematuria
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Foot-strike hemolysis
TreatmentAdditional Treatment
Additional Therapies
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Rule out iron-deficiency anemia.
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Self-limited condition; indexes return to pretraining levels after training is discontinued (5).
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Normal physiologic response; no treatment required (6)
References
1. Eichner ER. Sports medicine pearls and pitfalls: Nature's anticoagulant. Curr Sports Med Rep. 2009;8:2–3.
2. El-Sayed MS, Ali N, El-Sayed Ali Z. Haemorheology in exercise and training. Sports Med. 2005;35:649–670.
3. Sawka MN, Convertino VA, Eichner ER, et al. Blood volume: importance and adaptations to exercise training, environmental stresses, and trauma/sickness. Med Sci Sports Exerc. 2000;32:332–348.
4. Chatard JC, Mujika I, Guy C, et al. Anaemia and iron deficiency in athletes. Practical recommen-dations for treatment. Sports Med. 1999;27:229–240.
5. Shaskey DJ, Green GA. Sports haematology. Sports Med. 2000;29:27–38.
6. Carlson DL, Mawdsley RH. Sports anemia: a review of the literature. Am J Sports Med. 1986;14:109–112.
Additional Reading
Balaban EP. Sports anemia. Clin Sports Med. 1992;11:313–325.
Raunikar RA, Sabio H. Anemia in the adolescent athlete. Am J Dis Child. 1992;146:1201–1205.
Watts E. Athletes' anaemia. A review of possible causes and guidelines on investigation. Br J Sports Med. 1989;23:81–83.
Weight LM, Darge BL, Jacobs P. Athletes' pseudoanemia. Eur J Appl Physiol. 1991;62:358–362.
CodesICD9
285.9 Anemia, unspecified
Clinical Pearls
Iron supplementation does not affect occurrence or improve lab values, nor is it necessary unless there is a coexisting iron-deficiency anemia.