Contributions of acetylcholine and nitric oxide to forearm blood flow at exercise onset and recovery

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Contributions of acetylcholine and nitric oxide to forearm blood flow at exercise onset and recovery

J. K. Shoemaker¹, J. R. Halliwill², R. L. Hughson¹, and M. J. Joyner²

¹ Department of Kinesiology, University of Waterloo, Waterloo, Ontario, Canada N2L 3G1; and ² Department of Anesthesia, Mayo Clinic, Rochester, Minnesota 55905

The contributions of acetylcholine and/or nitric oxide (NO) to the rapid changes in human forearm blood flow (FBF) at theonset and recovery from mild exercise were studied in eight subjects.Rhythmic handgrip contractions were performed during brachialartery infusions of saline (2 ml/min; control), atropine (0.2mg over 3 min), to block acetylcholine binding to muscarinic receptors,or atropine + N^G-monomethyl-L-arginine (L-NMMA; 4 mg/min for 4 min), to additionallyinhibit NO synthase. Brachial artery mean blood velocity (MBV;pulsed Doppler ultrasound) and diameter (echo Doppler) were measuredcontinuously, and FBF was calculated. Atropine reduced acetylcholine-inducedincreases in FBF by ~71% (P < 0.05). FBF at rest was reduced byatropine and further reduced with atropine + L-NMMA. Both drugconditions reduced FBF during exercise by ~10% compared with control,with no difference between drug treatments. Brachial artery diameterwas unchanged from rest by exercise, recovery, and drug treatments.Neither drug treatment altered the rate or magnitude of the increasein FBF above rest. Peak FBF after exercise was reduced by atropineand atropine + L-NMMA. Total FBF during 5 min of recovery wasreduced with atropine + L-NMMA compared with control and atropine.The results suggest that 1) acetylcholine and NO mechanisms additivelycontribute to FBF levels at rest, 2) a cholinergic mechanism adjuststhe absolute FBF levels during exercise, 3) neither acetylcholinenor NO is essential to observe the normal time course or magnitudeof the exercise response, and 4) NO contributes to the FBF responseduring recovery from exercise.

brachial artery; pulsed Doppler; echo Doppler; vasodilation; atropine; N^G-monomethyl-L-arginine

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				M. J. Joyner and B. W. Wilkins Exercise hyperaemia: is anything obligatory but the hyperaemia? J. Physiol., September 15, 2007; 583(3): 855 - 860. [Abstract] [Full Text] [PDF]

				S. E. Bearden Advancing age produces sex differences in vasomotor kinetics during and after skeletal muscle contraction Am J Physiol Regulatory Integrative Comp Physiol, September 1, 2007; 293(3): R1274 - R1279. [Abstract] [Full Text] [PDF]

				K. K. Kalliokoski, H. Langberg, A. K. Ryberg, C. Scheede-Bergdahl, S. Doessing, A. Kjaer, M. Kjaer, and R. Boushel Nitric oxide and prostaglandins influence local skeletal muscle blood flow during exercise in humans: coupling between local substrate uptake and blood flow Am J Physiol Regulatory Integrative Comp Physiol, September 1, 2006; 291(3): R803 - R809. [Abstract] [Full Text] [PDF]

				E. A. Martin, W. T. Nicholson, J. H. Eisenach, N. Charkoudian, and M. J. Joyner Bimodal distribution of vasodilator responsiveness to adenosine due to difference in nitric oxide contribution: implications for exercise hyperemia J Appl Physiol, August 1, 2006; 101(2): 492 - 499. [Abstract] [Full Text] [PDF]

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				L.-E. Chen, K. Liu, W.-N. Qi, E. Joneschild, X. Tan, A. V. Seaber, J. S. Stamler, and J. R. Urbaniak Role of nitric oxide in vasodilation in upstream muscle during intermittent pneumatic compression J Appl Physiol, February 1, 2002; 92(2): 559 - 566. [Abstract] [Full Text] [PDF]

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				R. W. GRANGE, E. ISOTANI, K. S. LAU, K. E. KAMM, P. L. HUANG, and J. T. STULL Nitric oxide contributes to vascular smooth muscle relaxation in contracting fast-twitch muscles Physiol Genomics, February 7, 2001; 5(1): 35 - 44. [Abstract] [Full Text] [PDF]

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