Objective: Vascular compliance is an essential component of cerebral blood flow regulation. Prior work has shown cerebral vasodilation (elicited by hypercapnia) reduces cerebrovascular compliance (Ci); however, this work has yet to be translated to other vasoactive compounds. Insulin has important vasodilatory effects in the peripheral circulation, but less is known about the role of insulin in cerebrovascular control. Herein, we hypothesized both peripheral (intravenous) and central (intranasal) insulin administration would increase indices of cerebral blood flow and reduce Ci in healthy young adults. Methods: Twenty-five healthy young adults (8 female; 26±7 yrs, 25±3 kg/m2) were assigned to two separate protocols (NCT05244694, NCT05153395). Middle cerebral artery blood velocity (MCAv, transcranial Doppler ultrasound) was measured at baseline and under two study conditions: 1) at the end of a 60 min hyperinsulinemic euglycemic infusion, and 2) 60 min following 160 IU of intranasal insulin. Indices of Ci were calculated using a modified Windkessel model applied to blood pressure (finger photoplethysmography) and corresponding MCAv waveforms collected over a 5-min period (10 waveforms) at baseline and during the aforementioned insulin conditions. Results: Blood glucose remained unchanged throughout both protocols (both p>0.05). MCAv was maintained over time under both insulin conditions (protocol 1: 60±13 to 62±17 cm/s, p=0.635; protocol 2: 58±9 to 53±14 cm/s, p=0.146). In contrast, Ci decreased (0.00028±0.00010 to 0.00021±0.00007 cm/s/mmHg, p=0.010) from baseline during peripheral (intravenous) insulin administration. No change in Ci (0.00049±0.00025 to 0.00040±0.00018 cm/s/mmHg, p=0.189) were observed following intranasal insulin administration. Conclusions: Contrary to our hypothesis, there was no effect of peripheral or central insulin administration on resting MCAv in healthy young adults. However, intravenous (but not intranasal) insulin reduced Ci by approximately 25% from baseline values. These findings advance our understanding of cerebrovascular control mechanisms during insulin exposure and provide the opportunity to extend this work to diseased states characterized by insulin resistance, including diabetes. CAFNR Joy of Discovery (JKL, JP). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.