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International Archives of Occupational and Environmental Health

Erschienen in:

01.03.2011 | Original Article

Effects of temperature on reductions in finger blood flow induced by vibration

verfasst von: Ying Ye, Michael J. Griffin

Erschienen in: International Archives of Occupational and Environmental Health | Ausgabe 3/2011

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Abstract

Purpose

To investigate how temperature influences changes in finger circulation induced by hand-transmitted vibration in healthy subjects, and the variability in individual response to both vibration and temperature.

Methods

With two room temperatures (20 and 28°C), finger blood flow (FBF) and finger skin temperature (FST) were measured on the left middle fingers of 12 subjects at 1-min intervals during three successive 10-min periods. A 5-N static force was applied throughout the 30-min period, and sinusoidal 125-Hz vibration at 44 ms⁻² rms. (unweighted) was applied to the right hand during the second of the three 10-min periods.

Results

Before exposure to vibration, both FBF and FST were greater with the higher room temperature. Finger blood flow in the left hand reduced during vibration of the right hand. The reduction in absolute FBF differed between the two room temperatures, but the percentage reduction in FBF relative to FBF before exposure to vibration was similar. After cessation of vibration, there was continued reduction in FBF with both room temperatures. Before and after vibration exposure, the FST was correlated with FBF and the FBF and FST at 20°C were correlated with the FBF and FST at 28°C.

Conclusions

Vibration of one hand can reduce finger blood flow and skin temperature on the unexposed hand, with the reduction dependent on temperature. The absolute reduction in FBF was greater with the higher room temperature, but the percentage reduction in FBF relative to FBF before vibration exposure was similar. Those with greater finger blood flow before vibration tend to have greater blood flow during vibration, and those with greater finger blood flow with one temperature tend to have greater blood flow with another temperature.

Bornmyr S, Castenfors J, Evander E, Olsson G, Hjortsberg U, Wollmer P (2001) Effect of local cold provocation on systolic blood pressure and skin blood flow in the finger. Clin Physiol 21:570–575CrossRef

Bovenzi M, Griffin MJ (1997) Haemodynamic changes in ipsilateral and contralateral fingers caused by acute exposures to hand transmitted vibration. Occup Environ Med 54:566–576CrossRef

Bovenzi M, Griffin MJ, Ruffell CM (1995) Acute effects of vibration on digital circulatory function in healthy men. Occup Environ Med 52:834–841CrossRef

Bovenzi M, Lindsell CJ, Griffin MJ (1998) Duration of acute exposure to vibration and finger circulation. Scand J Work Environ Health 24(2):130–137

Bovenzi M, Lindsell CJ, Griffin MJ (1999) Magnitude of acute exposure to vibration and finger circulation. Scand J Work Environ Health 25(3):278–284

Bovenzi M, Lindsell CJ, Griffin MJ (2000) Acute vascular responses to the frequency of vibration transmitted to the hand. Occup Environ Med 57(6):422–430CrossRef

Bovenzi M, Welsh AJL, Griffin MJ (2004) Acute effects of continuous and intermittent vibration on finger circulation. Int Arch Occup Environ Health 77(4):255–263CrossRef

Bovenzi M, Welsh AJL, Della Vedova A, Griffin MJ (2006) Acute effects of force and vibration on FBF. Occup Environ Med 63:84–91CrossRef

Bovenzi M, D’Agostin F, Rui F, Negro C (2008) A longitudinal study of finger systolic blood pressure and exposure to hand-transmitted vibration. Int Arch Occup Environ Health 81(5):613–623CrossRef

Cleophas TJM, Fennis JFN, van’t Laar A (1982) Finger skin temperature after finger-cooling test: influence of air temperature and smoking. J Appl Physiol 52:1167–1171

Egan CE, Espie BH, McGrann S, McKenna KM, Allen JA (1996) Acute effects of vibration on peripheral blood flow in healthy subjects. Occup Environ Med 53:663–669CrossRef

Färkillä M, Pyykkö I (1979) Blood flow in the contralateral hand during vibration and hand grip contractions of lumberjacks. Scand J Work Environ Health 5:368–374

Fox RH, Edholm OE (1963) Nervous control of the cutaneous circulation. Br Med Bull 19:110–114

Furuta M, Sakakibara H, Miyao M, Kondo T, Yamada S (1991) Effect of vibration frequency on finger blood flow. Int Arch Occup Environ Health 63:221–224CrossRef

Greenfield ADM, Whitney RJ, Mowbray JF (1963) Methods for the investigation of peripheral blood flow. Br Med Bull 19:101–109

Griffin MJ (1997) Measurement, evaluation, and assessment of occupational exposure to hand-transmitted vibration. Occup Environ Med 54:73–89CrossRef

Griffin MJ, Bovenzi M, Nelson CM (2003) Dose-response patterns for vibration-induced white finger. Occup Environ Med 60(1):16–26CrossRef

Griffin MJ, Welsh AJL, Bovenzi M (2006) Acute response of finger circulation to force, vibration applied at the palm of the hand. Scand J Work Environ Health 32(5):383–391

Harada N, Iwamoto M, Laskar MS, Hirosawa I, Nakamoto M, Shirono S, Wakui T (1998) Effects of room temperature, seasonal condition and food intake on finger skin temperature during cold exposure test for diagnosing hand-arm vibration syndrome. Ind Health 36:166–170CrossRef

Hyvärinen J, Pyykkö I, Sundberg S (1973) Vibration frequencies and amplitudes in the aetiology of traumatic vasospastic disease. Lancet Issue 7807:791–794CrossRef

International Organization for Standardization (2001) Mechanical vibration: guidelines for the measurement and the assessment of human response to hand-transmitted vibration. International Standard, ISO 5349-1

International Organization for Standardization (2005) Mechanical vibration and shock: cold provocation tests for the assessment of peripheral vascular function. Part 2: Measurement and evaluation of finger systolic blood pressure. International Standard, ISO 14835-2

Liedtke AJ, Schmid PG (1969) Effect of vibration on total vascular resistance in the forelimb of the dog. J Appl Physiol 26:95–100

Lindblad LE, Lorenz RR, Sherpherd JT, Vanhoutte PM (1986) Effects of vibration on a canine cutaneous artery. Am J Physiol 250:H519–H523

Ljung B, Sivertsson R (1975) Vibration-induced inhibition of vascular smooth muscle contraction. Blood Vessels 12:38–52

Mahbub MH, Harada N (2008) Digital blood flow and temperature response in palmar and dorsal skin induced by short-term vibration exposure while grasping a vibratory handle. Int Arch Occup Environ Health 81:889–897CrossRef

Mahbub MH, Inoue M, Yokoyama K, Laskar MS, Ohnari H, Suizu K, Inagaki J, Takahashi Y, Harada N (2006) Assessment of room temperature influence on finger blood flow response induced by short-term grasping of vibrating handle. Int Arch Occup Environ Health 79:22–26CrossRef

Matikainen E, Leinonen H, Juntunen J, Seppäläinen AM (1987) The effect of exposure to high and low frequency hand-arm vibration on finger systolic pressure. Eur J Appl Physiol 56:440–443CrossRef

Mckenna KM, Blann AD, Allen JA (1994) Vascular responses in chain saw operators. Occup Environ Med 51:366–370CrossRef

Mirbod SM, Yoshida H, Jamali M, Miyashita K, Takada H, Inaba R, Iwata H (1998) Finger skin temperature and laser-doppler finger blood flow in subjects exposed to hand-arm vibration. Ind Health 36:171–178CrossRef

Nakamura H, Okazawa T, Nagase H, Yoshida M, Ariizumi M, Okada A (1996) Change in digital blood flow simultaneous reduction in plasma endothelin induced by hand-arm vibration. Int Arch Occup Environ Health 68:115–119CrossRef

Nasu T (1977) Changes of the skin temperature caused by local vibratory stimulation in normals and patients with vibration syndrome. Yonago Acta Medica 21:83–99

Ohhashi T, Ikomi F (1990) Vibration-induced increase of the lymph flow rate in canine hindlimb with special reference to Raynaund’s phenomenon in vibration disease. In: Okada A, Taylor W, Dupuis H (eds) Hand-arm vibration. Kyoei Press, Kanazawa, pp 19–22

Roddie IC (1983) Circulation to skin and adipose tissue. In: Handbook of physiology. The Cardiovascular system. Peripheral circulation and organ blood flow, sec 2, vol 3, chapter 10. American Physiological Society, Bethesda, pp 285–317

Sakakibara H, Iwase S, Mano T, Watanabe T, Kobayashi F, Furuta M (1990) Skin sympathetic activity in the tibial nerve triggered by vibration applied to the hand. Int Arch Occup Environ Health 62:455–458CrossRef

Sandover J, Louw J (1992) Acute effects of grip force and vibration on finger temperature. In: Presented at the 6th international conference on hand-arm vibration, Sankt Augustin, pp 211–218

Thompson AJL, Griffin MJ (2009) Effect of the magnitude and frequency of hand-transmitted vibration on finger blood flow during and after exposure to vibration. Int Arch Occup Environ Health 82:1151–1162CrossRef

Titel: Effects of temperature on reductions in finger blood flow induced by vibration
verfasst von: Ying Ye
Michael J. Griffin
Publikationsdatum: 01.03.2011
Verlag: Springer-Verlag
Erschienen in: International Archives of Occupational and Environmental Health / Ausgabe 3/2011
Print ISSN: 0340-0131
Elektronische ISSN: 1432-1246
DOI: https://doi.org/10.1007/s00420-010-0560-0

Springer Medizin

Abstract

Purpose

Methods

Results

Conclusions

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