Effects of acute bouts of endurance exercise on retinal vessel diameters are age and intensity dependent

M Nussbaumer, L Donath, M Fischer, J Schäfer, O Faude, L Zahner, A Schmidt-Trucksäss, H Hanssen, M Nussbaumer, L Donath, M Fischer, J Schäfer, O Faude, L Zahner, A Schmidt-Trucksäss, H Hanssen

Abstract

Alterations of retinal vessel diameters are associated with increased cardiovascular risk. We aimed to investigate changes in retinal vessel diameters in response to acute dynamic exercise of different intensities and whether these changes are age dependent. Seventeen healthy seniors (median (IQR) age 68 (65, 69) years) and 15 healthy young adults (median (IQR) age 26 (25, 28) years) first performed a maximal treadmill test (MTT) followed by a submaximal treadmill test (SMTT) and a resting control condition in randomised order. Central retinal arteriolar (CRAE) and central retinal venular (CRVE) diameter equivalents were measured before as well as 5 (t5) and 40 (t40) minutes after exercise cessation using a static retinal vessel analyser. Both exercise intensities induced a significant dilatation in CRAE and CRVE at t5 compared to the control condition (P < 0.001). At t40, the mean increase in CRAE and CRVE was greater for MTT compared to that for SMTT (CRAE 1.7 μm (95 % confidence interval (CI) -0.1, 3.6; P = 0.061); CRVE 2.2 μm (95 % CI 0.4, 4.1; P = 0.019)). However, the estimated difference at t5 between seniors and young adults in their response to MTT compared to SMTT was 5.3 μm (95 % CI 2.0, 8.5; P = 0.002) for CRAE and 4.1 μm (95 % CI -0.4, 8.6; P = 0.076) for CRVE. Wider arteries and veins after maximal versus submaximal exercise for seniors compared to young adults suggest that myogenic vasoconstriction in response to exhaustive exercise may be reduced in seniors. Age-related loss of vascular reactivity has clinical implications since the arteriolar vasoconstriction protects the retinal capillary bed from intraluminal pressure peaks.

Figures

**Fig. 1**
Participants were examined in a cross-over design. At the first visit, all study participants performed a maximal treadmill test (*MTT*). At the second and third visits, participants performed a submaximal 2-km treadmill test (*SMTT*) and a control condition (CC) in randomised order. Central retinal arteriolar (*CRAE* (in micrometre)) and venular (*CRVE* (in micrometre)) equivalents were measured before and after exercise cessation using a static retinal vessel analyser (*SVA*)

**Fig. 2**
Retinal vessel diameters at baseline as well as 5 min (t5) and 40 min (t40) after a maximal treadmill test (*MTT*), a submaximal 2-km treadmill test (*SMTT*) and a resting control condition (CC). a Central retinal arteriolar equivalent (*CRAE* (in micrometre)). b Central retinal venular equivalent (CRVE (in micrometre))

**Fig. 3**
Differences in retinal vessel diameter between maximal treadmill test (*MTT*), submaximal 2-km treadmill test (*SMTT*) and resting control condition (CC) for seniors and for young adults. a Difference in central retinal arteriolar equivalent (*CRAE* (in micrometre)) between *SMTT* and CC for seniors and for young adults. b Difference in *CRAE* between *MTT* and CC for seniors and for young adults. c Difference in *CRAE* between *MTT* and *SMTT* for seniors and for young adults. d Difference in central retinal venular equivalent (*CRVE* (in micrometre)) between *SMTT* and CC for seniors and for young adults. e Difference in *CRVE* between *MTT* and CC for seniors and for young adults. f Difference in *CRVE* between *MTT* and *SMTT* for seniors and for young adults

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Source: PubMed

Effects of acute bouts of endurance exercise on retinal vessel diameters are age and intensity dependent

Abstract

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References

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