Forearm norepinephrine spillover during standing, hyperinsulinemia, and hypoglycemia

Deanna S. Paramore, Carmine G. Fanelli, Suresh D. Shah, and Philip E. Cryer

Division of Endocrinology, Diabetes, and Metabolism, General Clinical Research Center and the Diabetes Research and Training Center, Washington University School of Medicine, St. Louis, Missouri 63110

    ABSTRACT
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Abstract
Introduction
Methods
Results
Discussion
References

Plasma norepinephrine (NE) concentrations are a fallible index of sympathetic neural activity because circulating NE can be derived from sympathetic nerves, the adrenal medullas, or both and because of regional differences in sympathetic neural activity. We used isotope dilution measurements of systemic and forearm NE spillover rates (SNESO and FNESO, respectively) to study the sympathochromaffin system during prolonged standing, hyperinsulinemic euglycemia, and hyperinsulinemic hypoglycemia in healthy humans. Prolonged standing led to decrements in blood pressure without increments in heart rate, the pattern of incipient vasodepressor syncope. FNESO was not increased (0.58 ± 0.20 to 0.50 ± 0.21 pmol · min-1 · 100 ml tissue-1), suggesting that the approximately twofold increments in plasma NE and SNESO were derived from sympathetic nerves other than those in the forearm (with a possible contribution from the adrenal medullas). Hyperinsulinemia per se (euglycemia maintained) stimulated sympathetic neural activity, as evidenced by increments in FNESO (0.57 ± 0.11 to 1.25 ± 0.25 pmol · min-1 · 100 ml tissue-1, P < 0.05), but not adrenomedullary activity. Hypoglycemia per se stimulated adrenomedullary activity (plasma epinephrine from 190 ± 70 to 1720 ± 320, pmol/l, P < 0.01). Although SNESO (P < 0.05) and perhaps plasma NE (P < 0.06) were raised to a greater extent during hyperinsulinemic hypoglycemia than during hyperinsulinemic euglycemia, FNESO was not. Thus these data do not provide direct support for the concept that hypoglycemia per se also stimulates sympathetic neural activity.

sympathetic nervous system; adrenal medullas; epinephrine; hypoglycemia

    INTRODUCTION
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Abstract
Introduction
Methods
Results
Discussion
References

ALTHOUGH THE PLASMA norepinephrine (NE) concentration is often viewed as an index of sympathetic neural activity, circulating NE can be derived from sympathetic postganglionic neurons, the adrenal medullas, or both (45). Furthermore, the plasma NE concentration is the result of the rate of NE appearance in plasma [conventionally referred to as the NE spillover rate (16) because the vast majority of the NE released from axon terminals of sympathetic postganglionic neurons is dissipated locally by neuronal reuptake or metabolism and does not enter the circulation (45)] and the rate of NE disappearance from plasma (often expressed as the plasma NE metabolic clearance rate). Thus measurements of NE kinetics are required to document the extent to which an increment in the plasma NE concentration is the result of increased spillover (an index of release) or decreased clearance (16). Nonetheless, the systemic plasma NE spillover rate, like the plasma NE concentration, is a marker of sympathetic neural activity, adrenomedullary activity, or both. Furthermore, regional variations in sympathetic neural activity can complicate interpretation of the plasma NE concentration (16).

Approaches to quantitation of sympathetic neural activity per se include 1) direct measurement with microneurography (4, 46, 56), 2) measurement of tissue NE concentrations with microdialysis (24, 31), and 3) NE isotope dilution measurements across a specific organ or tissue that does not include the adrenal medullas (16). Although it is more sensitive than plasma NE concentrations to changes in sympathetic neural activity (22), microneurography is technically demanding, limited to measurement of muscle and skin sympathetic neural activity, and, because it becomes progressively more stressful over time, not optimal for prolonged or repeated experiments. Tissue NE levels are difficult to quantitate with microdialysis (10, 24, 31); not only is a sensitive assay required, but calibration is problematic. Based on these considerations, and given our earlier experience with measurements of systemic NE kinetics (32), we selected measurements of forearm NE kinetics (11, 29) to quantitate sympathetic neural activity. This requires only the addition of deep venous sampling and measurements of forearm blood flow (23) to the basic method (32).

The forearm NE spillover technique also has limitations. First, it provides only an index of sympathetic neural NE release because the vast bulk of NE released is dissipated locally and does not enter the circulation (45). Second, it reflects NE release in only one region and therefore cannot assess regional differences in sympathetic neural activity (34). Third, the tracer technique per se involves several assumptions. For example, the fundamental assumption of the systemic NE clearance method and thus the systemic NE spillover calculation that the tracer mixes with a constant fraction of NE released at sympathetic nerve terminals has been challenged (10, 14). Furthermore, although we have found no differences between systemic NE kinetic data calculated from arterial and arterialized venous sampling but substantially higher values calculated from venous sampling (32), the optimal sampling site has not been determined (40). Nonetheless, as an index of NE release from sympathetic postganglionic neurons, and thus of sympathetic neural activity, forearm NE spillover rates (FNESO) have been found to be increased during lower body negative pressure (27, 29), during euglycemic hyperinsulinemia (29), during angiotensin II infusion (11), and after a meal (54). We used this technique to distinguish sympathetic neural from adrenomedullary activation during prolonged standing, hyperinsulinemic euglycemia, and hyperinsulinemic hypoglycemia in healthy human subjects.

    METHODS
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Abstract
Introduction
Methods
Results
Discussion
References

Subjects. Five healthy subjects (3 women and 2 men) gave their written consent to participate in study 1. Their mean ± SD age was 30 ± 5 yr (range 24-36 yr), and their mean body mass index (BMI) was 24.2 ± 7.6 kg/m2 (range 16.6-36.6 kg/m2). Five healthy subjects (3 women and 2 men) gave their written consent to participate in study 2. Their mean ± SD age was 35 ± 4 yr (range 28-40 yr), and their mean BMI was 23.6 ± 1.5 kg/m2 (range 22.2-25.5 kg/m2). Both studies were approved by the Washington University Radioactive Drug Research Committee and the Washington University Human Studies Committee and were performed in the outpatient facilities of the Washington University General Clinical Research Center (GCRC).

Protocols. Subjects presented to the GCRC early in the morning after an overnight fast. A catheter was inserted in a retrograde fashion in a deep antecubital vein in the dominant arm; this was flushed frequently with saline. In the contralateral arm, intravenous lines were inserted into a hand vein, with that hand kept in an ~65°C box to provide arterialized venous samples and in an antecubital vein for infusions ([3H]NE in both studies and, in study 2, insulin and glucose). Equipment for venous occlusion plethysmography (venous occlusion cuff, mercury strain gauge, and wrist occlusion cuff) was placed on the arm with the deep antecubital intravenous catheter.

In study 1, subjects were studied on two occasions in random sequence, separated by at least 1 mo, one time in the supine position throughout [supine in the first 30-min time segment (T1) and supine in the second 30-min time segment (T2)], the supine to supine limb, and one time in the supine position in T1 and after 30-60 min in the standing position in T2 (60 min in the first two subjects, who found this difficult to complete, and 30 min in the next three subjects), the supine to prolonged standing limb. In study 2 subjects were studied, in the supine position, on three occasions in random sequence each separated by at least 1 mo, one time during saline infusion in T1, T2, and the third time segment (T3), the control limb, one time during saline infusion in T1 and insulin infusion with maintenance of euglycemia (see below) in T2 and T3, the euglycemic limb, and one time during saline infusion in T1, insulin infusion with euglycemia in T2, and insulin infusion with hypoglycemia (see below) in T3, the euglycemic to hypoglycemic limb. Arterialized venous and deep antecubital venous samples (obtained simultaneously) for NE mass and radioactivity, forearm blood flow measurements, arterialized venous samples for hormone and metabolic substrate/intermediate levels, assessments of symptoms, and heart rate and blood pressure measurements were obtained serially, and the electrocardiogram was monitored throughout during hypoglycemia.

NE kinetics were calculated from arterialized venous samples obtained 20, 25, and 30 min into 30-min infusions of [3H]NE (levo-[ring-2,5,6-3H]NE, 40-60 Ci/mmol; New England Nuclear, Boston, MA; 10 nCi · kg-1 · min-1) as described previously (32). [3H]NE concentrations and NE specific activities (NE SA) were determined after organic extraction of NE from plasma (32). The systemic NE metabolic clearance rate (SNEMCR) and spillover rate (SNESO) were calculated as
SNEMCR (l/min) = <FR><NU>[<SUP>3</SUP>H]NE IR (dpm/min)</NU><DE>[<SUP>3</SUP>H]NE concentration (dpm/l)</DE></FR>
where [3H]NE IR is the [3H]NE infusion rate, and
SNESO (nmol/min) = <FR><NU>[<SUP>3</SUP>H]NE IR (dpm/min)</NU><DE>NE SA (dpm/nmol)</DE></FR>
where NE SA is the norepinephrine specific activity. The forearm NE metabolic clearance rate (FNEMCR) and spillover rate (FNESO) (11, 29) were calculated from forearm plasma flow [FPF = forearm blood flow(1 - hematocrit) in ml · min-1 · 100 ml tissue-1] and forearm fractional extraction of NE (Fex [3H]NE)
F<SUB>ex</SUB> [<SUP>3</SUP>H]NE (unitless) = <FR><NU>[<SUP>3</SUP>H]NE<SUB>A</SUB> − [<SUP>3</SUP>H]NE<SUB>V</SUB></NU><DE>[<SUP>3</SUP>H]NE<SUB>A</SUB></DE></FR>
where the subscripts A and V indicate arterial and venous, respectively. Hence
FNEMCR (ml ⋅ min<SUP>−1</SUP> ⋅ 100 ml tissue<SUP>−1</SUP>) = F<SUB>ex</SUB>[<SUP>3</SUP>H]NE × FPF
FNESO (nmol ⋅ min<SUP>−1</SUP> ⋅ 100 ml tissue<SUP>−1</SUP>) = [(NE<SUB>V</SUB> − NE<SUB>A</SUB>) + (NE<SUB>A</SUB> × F<SUB>ex</SUB>[<SUP>3</SUP>H]NE)] × FPF
Forearm blood flow was measured by venous occlusion plethysmography (Parks Medical Electronics, Aloha, OR; see Ref. 21) at the 20-, 25-, and 30-min time points during each [3H]NE infusion along with measurements of NE mass and radioactivity at the same time points. To exclude the hand from the measurement of blood flow, the wrist cuff was inflated to ~230 mmHg for 2 min before recordings and was maintained during the recordings. Each blood flow value was the mean of five consecutive recordings.

In study 1, after instrumentation and a 30-min rest period, [3H]NE was infused for 30 min, there was a 30-min washout period, and [3H]NE was again infused for 30 min. Isotopic steady state is achieved after <20 min (32). On one occasion the subject remained supine throughout; on the other occasion the subject was supine during the first [3H]NE infusion and standing during the second infusion.

In study 2, again after instrumentation and a 30-min rest period, [3H]NE was infused over 30 min three times with 30-min washout periods between infusions, on three occasions in random sequence: one time with saline infusion through all three segments (T1, T2, and T3); one time with saline infusion in T1 and insulin infusion (12.0 pmol · kg-1 · min-1) in T2 and T3 with euglycemia (~4.6 mmol/l) maintained by variable 20% glucose infusion through T2 and T3 (43); and one time with saline infusion in T1, insulin infusion in T2 and T3, euglycemia (~4.6 mmol/l) in T2, and hypoglycemia (~2.8 mmol/l) in T3 (43).

Analytical methods. Plasma glucose was measured with a glucose oxidase method (Beckman Glucose Analyzer 2; Beckman Instruments, Fullerton, CA). Plasma NE and epinephrine concentrations were measured with a single isotope derivative (radioenzymatic) method (44), and those of insulin (28), C-peptide (28), glucagon (15), pancreatic polypeptide (20), cortisol (18), and growth hormone (42) were measured with radioimmunoassays. Serum nonesterified fatty acid levels were measured with an enzymatic colorimetric method (26), and blood beta -hydroxybutyrate (37), lactate (30), and alanine (7) levels were measured with enzymatic techniques. Neurogenic (autonomic) and neuroglycopenic symptom scores were determined as described previously (43, 52).

Statistical methods. Contrasts over time (T1 vs. T2 in study 1 and T1 vs. T2 and T3 in study 2) within each study limb [i.e., each study day: the supine to supine day and the supine to prolonged standing day in study 1 and the saline infusion day (control limb), the saline then insulin and glucose infusion day (euglycemic limb), and the saline then insulin then hypoglycemia day (euglycemic to hypoglycemic limb) in study 2] were analyzed by t-test for paired data. Contrasts between limbs were analyzed by general linear models procedure repeated measures analysis of variance (ANOVA) for limb × time interactions. In this report, P values for time contrasts are shown without further notation, and those for limb × time interactions are shown with the notation ANOVA. P values <0.05 were considered to indicate statistically significant differences. Data are expressed as means ± SE except where the SD is specified.

    RESULTS
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Abstract
Introduction
Methods
Results
Discussion
References

Study 1. Mean blood pressures, which did not change over time in the T1 and T2 time segments in the supine to supine limb, decreased from 93 ± 8 mmHg in T1 to 69 ± 6 mmHg in T2 (P < 0.02) in the supine to prolonged standing limb (Fig. 1). There was a significant limb × time interaction (ANOVA, P < 0.02). There were no changes in heart rates (Fig. 1). Plasma pancreatic polypeptide concentrations, which did not change over time in the supine to supine limb, increased from 11 ± 2 to 42 ± 9 pmol/l (P < 0.01) in the supine to prolonged standing limb (Fig. 2). There was a significant limb × time interaction (ANOVA, P < 0.01). Forearm blood flows, which did not change over time in the supine to supine limb, fell from 1.79 ± 0.29 to 0.72 ± 0.21 ml · min-1 · 100 ml tissue-1 (P < 0.05) in the supine to prolonged standing limb (Fig. 2). There was a significant limb × time interaction (ANOVA, P < 0.05). Plasma epinephrine concentrations, which did not change over time in the supine to supine limb, increased from 130 ± 30 to 630 ± 70 pmol/l (P < 0.01) in the supine to prolonged standing limb (Fig. 3). There was a significant limb × time interaction (ANOVA, P < 0.01). Plasma NE concentrations, which did not change in the supine to supine limb, increased from 0.72 ± 0.12 to 1.53 ± 0.26 nmol/l (P < 0.01) in the prolonged standing limb (Fig. 3). There was a significant limb × time interaction (ANOVA, P < 0.01).


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Fig. 1.   Mean ± SE blood pressures (A) and heart rates (B) in healthy subjects with the subjects supine (Su, open bars) during two consecutive periods separated by 30 min on one occasion and supine and then standing (St, filled bars) for 30-60 min on another occasion in study 1. * Significant difference from the baseline value on the same occasion.


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Fig. 2.   Mean ± SE plasma pancreatic polypeptide concentrations (A) and forearm blood flow rates (B) in healthy subjects with the subjects supine (open bars) during two consecutive periods separated by 30 min on one occasion and supine and then standing (filled bars) for 30-60 min on another occasion in study 1. * Significant differences from the baseline values on the same occasion.


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Fig. 3.   Mean ± SE plasma epinephrine concentrations (A) and plasma norepinephrine (NE) concentrations (B) in healthy subjects with the subjects supine (open bars) during two consecutive periods separated by 30 min on one occasion and supine and then standing (filled bars) for 30-60 min on another occasion in study 1. * Significant differences from the baseline values on the same occasion.

NE SA were stable at the 20-, 25-, and 30-min sampling times with the subjects in the supine and in the standing positions [data not shown but as also documented previously (30)]. Thus mean data from these three samples were used to calculate NE kinetic values during the final 10 min of each 30-min [3H]NE infusion. Systemic NE spillover rates (SNESO), which did not change over time in the supine to supine limb, increased from 2.16 ± 0.39 to 4.62 ± 1.29 nmol/min (P < 0.05) in the supine to prolonged standing limb (Fig. 4). There was a significant limb × time interaction (ANOVA, P < 0.05). However, FNESO, which did not change over time in the supine to supine limb, did not increase (0.58 ± 0.20 to 0.50 ± 0.21 pmol · min-1 · 100 ml tissue-1) in the prolonged standing limb (Fig. 4). SNEMCR and FNEMCR (data not shown) did not change significantly over time in either limb, and there was no significant limb × time interaction.


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Fig. 4.   Mean ± SE systemic (A) and forearm (B) NE spillover rates in healthy subjects with the subjects supine (open bars) during two consecutive periods separated by 30 min on one occasion and supine and then standing (filled bars) for 30-60 min on another occasion in study 1. * Significant difference from the baseline value on the same occasion.

Study 2. Plasma glucose concentrations were stable through the T1, T2, and T3 segments in the control (saline infusion) limb, through the T1 (saline) and the T2 and T3 (hyperinsulinemic euglycemia) time segments in the euglycemic limb, and during the T1 (saline) and T2 (hyperinsulinemic euglycemia) time segments of the euglycemic to hypoglycemic limb of the study (Fig. 5). Plasma glucose levels were decreased from 4.7 ± 0.1 mmol/l during the T2 time segment to 2.9 ± 0.1 mmol/l in the T3 time segment of the latter limb of the study (Fig. 5). Plasma insulin concentrations, which did not change over time in the control limb, were raised comparably during the T2 and T3 time segments in both the euglycemic and the euglycemic to hypoglycemic limbs (Table 1). There was not a significant limb × time interaction. Some of the insulin values were below the detection limit of 24 pmol/l and were assigned that value for calculation of the means. Plasma C-peptide concentrations, which did not change over time in the control limb, decreased during the T2 (P < 0.05) and T3 (P < 0.001) time segments in the euglycemic limb and the T2 (P < 0.05) time segment in the euglycemic to hypoglycemic limb (Table 1). C-peptide levels decreased further during hypoglycemia (T3 time segment in the euglycemic to hypoglycemic limb) compared with during euglycemic hyperinsulinemia (ANOVA, P < 0.01).


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Fig. 5.   Mean ± SE plasma glucose concentrations at the end of the T1, T2, and T3 time segments in the control limb, the euglycemic (Eu) limb, and the euglycemic to hypoglycemic (Euright-arrowHypo) limb in healthy subjects during saline infusions (open bars) and insulin infusions with euglycemia (crosshatched bars) or hypoglycemia (filled bar) in study 2.

                              
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Table 1.   Plasma insulin, C-peptide, pancreatic polypeptide, glucagon, growth hormone, and cortisol concentrations

Mean blood pressures, which did not change in the control and euglycemic limbs, decreased slightly in the euglycemic to hypoglycemic limb (P < 0.05; Table 2). There was a significant limb × time interaction (ANOVA, P < 0.05). Systolic and diastolic blood pressure patterns were similar (Table 2), again with significant limb × time interactions (both ANOVA, P < 0.05). Heart rates did not change significantly in any of the limbs (Table 2). Rates of forearm blood flow, which did not change during the control and the euglycemic limbs, increased from 1.48 ± 0.31 to 2.52 ± 0.49 ml · min-1 · 100 ml tissue-1 (P < 0.05) in the T3 time segment in the euglycemic to hypoglycemic limb (Fig. 6). The increase in forearm blood flow was greater in the euglycemic to hypoglycemic limb than in the euglycemic limb (ANOVA, P < 0.01) despite comparable hyperinsulinemia (Table 1).

                              
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Table 2.   Mean, systolic, and diastolic blood pressure and heart rate


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Fig. 6.   Mean ± SE forearm blood flow in the final 10 min of the T1, T2, and T3 segments in the control limb, the euglycemic limb, and the euglycemic to hypoglycemic limb in healthy subjects during saline infusions (open bars) and insulin infusions with euglycemia (crosshatched bars) or hypoglycemia (filled bar) in study 2. * Significant difference from the baseline value on the same occasion.

Plasma epinephrine concentrations, which did not change in the control and euglycemic limbs, increased from 190 ± 70 to 1,720 ± 320 pmol/l (P < 0.0001) in the T3 time segment in the euglycemic to hypoglycemic limb (Fig. 7). The increase in plasma epinephrine levels was greater in the euglycemic to hypoglycemic limb than in the euglycemic limb (ANOVA, P < 0.01). Plasma NE concentrations, which were unchanged in the control limb and did not increase significantly in the euglycemic limb, increased from 1.04 ± 0.15 to 1.57 ± 0.18 nmol/l (P < 0.05) in the T3 time segment in the euglycemic to hypoglycemic limb (Fig. 8). However, the T1 to T3 increase in plasma NE levels in the euglycemic to hypoglycemic limb was not significantly greater than the apparent increase in the euglycemic limb (ANOVA, P = 0.11), nor was the T2 to T3 increase (ANOVA, P = 0.05).


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Fig. 7.   Mean ± SE plasma epinephrine concentrations at the end of the T1, T2, and T3 segments in the control limb, the euglycemic limb, and the euglycemic to hypoglycemic limb in healthy subjects during saline infusions (open bars) and insulin infusions with euglycemia (crosshatched bars) or hypoglycemia (filled bar) in study 2. * Significant difference from the baseline value on the same occasion.


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Fig. 8.   Mean ± SE plasma NE concentrations at the end of the T1, T2, and T3 segments in the control limb, the euglycemic limb, and the euglycemic to hypoglycemic limb in healthy subjects during saline infusions (open bars) and insulin infusions with euglycemia (crosshatched bars) or hypoglycemia (filled bar) in study 2. * Significant difference from the baseline value on the same occasion.

In addition to decrements in endogenous insulin secretion, hypoglycemia elicited increments in plasma pancreatic polypeptide, glucagon, growth hormone, and cortisol concentrations (Table 1). Increments in each of these were significantly greater in the euglycemic to hypoglycemic limb than in the euglycemic limb (ANOVA, P < 0.01 for pancreatic polypeptide and glucagon and P < 0.05 for growth hormone and cortisol). Serum nonesterified fatty acid levels were suppressed during hyperinsulinemia in both the euglycemic (P < 0.001) and the euglycemic to hypoglycemic (P < 0.0001) limbs (Table 3). Blood beta -hydroxybutyrate patterns were similar (Table 3). Blood lactate concentrations, which did not change in the control limb and appeared to increase in the euglycemic limb, increased during the T2 time segment (P < 0.001) and the T3 time segment (P < 0.02) in the euglycemic to hypoglycemic limb (Table 3). Blood alanine concentrations did not change in any of the limbs (Table 3).

                              
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Table 3.   Nonesterified fatty acid, beta -hydroxybutyrate, lactate, and alanine concentrations

NE SA were stable at the 20-, 25-, and 30-min sampling times in all three limbs (data not shown). Thus mean data from these three samples were used to calculate NE kinetic values during the final 10 min of each 30-min [3H]NE infusion in each time segment of each limb. SNESO, which did not change in the control limb and did not increase significantly in the euglycemic limb, increased from 3.45 ± 0.69 to 5.59 ± 0.88 nmol/min (P < 0.05) in the euglycemic to hypoglycemic limb (Fig. 9). Although the T1 to T3 increase in SNESO in the euglycemic to hypoglycemic limb was not significantly grater than that in the euglycemic limb (ANOVA, P = 0.14), the T2 to T3 increase was greater in the euglycemic to hypoglycemic limb (ANOVA, P < 0.05). FNESO, which did not change in the control limb, increased from 0.57 ± 0.11 to 1.25 ± 0.25 pmol · min-1 · 100 ml tissue-1 (P < 0.05) in the euglycemic limb and from 0.36 ± 0.08 to 1.03 ± 0.37 pmol · min-1 · 100 ml tissue-1 (P < 0.05) in the euglycemic to hypoglycemic limb (Fig. 10). The increase in forearm NE spillover was not significantly greater in the euglycemic to hypoglycemic limb than in the euglycemic limb. SNEMCR and FNEMCR did not change over time in any of the three limbs (data not shown). Neurogenic symptom scores, which did not change in the control and euglycemic limbs, increased from 1.2 ± 0.4 to 4.0 ± 0.9 (P < 0.02) in the euglycemic to hypoglycemic limb (other data not shown). Neuroglycopenic symptom scores did not change significantly over time in any of the three limbs (data not shown).


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Fig. 9.   Mean ± SE systemic NE spillover rates during the last 10 min of the T1, T2, and T3 segments in the control limb, the euglycemic limb, and the euglycemic to hypoglycemic limb in healthy subjects during saline infusions (open bars) and insulin infusions with euglycemia (crosshatched bars) or hypoglycemia (filled bar) in study 2. * Significant difference from the baseline value on the same occasion.


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Fig. 10.   Mean ± SE forearm NE spillover rates during the last 10 min of the T1, T2, and T3 segments in the control limb, the euglycemic limb, and the euglycemic to hypoglycemic limb in healthy subjects during saline infusions (open bars) and insulin infusions with euglycemia (crosshatched bars) or hypoglycemia (filled bar) in study 2. * Significant difference from the baseline value on the same occasion.

Relative increments in FNESO were consistently greater than those in SNESO under the various study conditions in study 2. During hyperinsulinemic euglycemia in the euglycemic limb of the study the increases were 1.9- vs. 1.4-fold, respectively, from the T1 to the T2 segment and 2.2- and 1.4-fold, respectively, from the T1 to the T3 segment; in the euglycemic to hypoglycemic limb they were 2.0- vs. 1.3-fold, respectively, from the T1 to the T2 segment. During hyperinsulinemic hypoglycemia in the euglycemic to hypoglycemic limb the increases were 2.8- vs. 1.6-fold, respectively, from the T1 to the T3 segment and 1.4- vs. 1.2-fold in the T2 to the T3 segment.

    DISCUSSION
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Abstract
Introduction
Methods
Results
Discussion
References

We used measurements of FNESO, coupled with those of SNESO and plasma NE and epinephrine concentrations, to distinguish sympathetic neural from adrenomedullary activation during prolonged standing, hyperinsulinemic euglycemia, and hyperinsulinemic hypoglycemia in healthy human subjects. The data indicate that increments in plasma NE concentrations (and SNESO) can be dissociated from sympathetic neural activity in one region, the forearm, during prolonged standing, that hyperinsulinemia per se stimulates the sympathetic neural but not the adrenomedullary component of the sympathochromaffin system, and that while hypoglycemia per se stimulates the adrenomedullary component it may not stimulate the sympathetic neural component.

Prolonged (30-60 min) standing was associated with decrements in systolic and diastolic (and therefore mean) blood pressures and forearm blood flow without an increment in heart rate, a pattern suggesting that sympathetic neural activity was no longer increased substantially, and parasympathetic neural activity was increased, in healthy young adults. This hemodynamic pattern is that of the vasodepressor (vasovagal, neurocardiogenic) response that can lead to syncope (53). There is considerable evidence, based on measurements of plasma NE concentrations (21, 41, 48, 58), cardiac and renal NE spillover rates (16), and microneurography (25, 35, 36, 57), that a decrease in sympathetic neural activity is a key component of the vasodepressor response. The present findings of increments in plasma NE concentrations and SNESO, but not FNESO, are consistent with that construct. Taken at face value the data suggest that the raised plasma NE concentrations and SNESO were the result of increased NE release from sympathetic nerves other than those in the forearm (16) (and to some extent from the adrenal medullas given the observed 5-fold increase in the plasma epinephrine concentration). In addition, the finding of increased plasma pancreatic polypeptide levels, a putative marker of pancreatic parasympathetic outflow (41), could explain the absence of an increase in heart rate if parasympathetic outflow to the heart parallels that to the pancreas. However, at the time of incipient vasodepressor syncope, when the subjects were studied, they still had measurable, albeit reduced, blood pressures and had not lost consciousness. Therefore, although likely less than shortly after standing, (6, 45, 51), net sympathetic neural activity must have been increased to some extent.

The assumption that infused labeled NE mixes with a constant fraction of NE released at sympathetic nerve terminals, which is implicit in the application of the clearance concept to the quantification of NE kinetics, has been challenged by Christensen and Knudsen (10). If this condition is not met when the capillary surface exchange area is increased (14) or decreased, the plasma NE spillover rate would be overestimated or underestimated, respectively. This might explain a reported discrepancy between muscle sympathetic nerve activity measured with microneurography and plasma NE concentrations (both increased) and plasma NE spillover (unchanged) during lower body negative pressure, a condition in which the capillary surface exchange area would be expected to be decreased (10). The latter would also be expected during prolonged standing in the present study; our methods did not include a measure of capillary surface exchange area (14). Thus the FNESO could have been underestimated. Finally, with respect to such technical issues, the calculated forearm NE plasma appearance rate, which includes an extraction term, has been reported to be influenced to a lesser degree by local changes in NE clearance and blood flow (7) than the spillover rate (8). However, the pattern of findings reported here was the same when expressed as the appearance rate, albeit with larger variances, as it was when expressed as the spillover rate in both study 1 and study 2.

Compared with the plasma NE concentration and the SNESO, the FNESO was more variable when measured three times with the subjects in the supine position, perhaps because of variation in the measurement of forearm blood flow.

To assess the extent to which increments in plasma NE concentrations during hyperinsulinemia and hypoglycemia are the result of sympathetic neural activation, adrenomedullary activation, or both, subjects were studied (in the supine position) during saline infusion, hyperinsulinemic euglycemia, and hyperinsulinemic hypoglycemia. Euglycemic hyperinsulinemia caused increments in FNESO and apparent increments in SNESO and plasma NE levels, with no change in plasma epinephrine concentrations. Thus hyperinsulinemia per se stimulates the sympathetic neural, but not the adrenomedullary, component of the sympathochromaffin system. This pattern, a significant increment in FNESO without significant increments in plasma NE or SNESO, suggests that the forearm NE spillover measurement, like microneurography (22), is a more sensitive measure of sympathetic neural activation than the plasma NE concentration (or the SNESO) at least under this condition.

Our finding of unaltered plasma epinephrine concentrations during hyperinsulinemic euglycemia is consistent with most, but not all, previous studies. For example, Tack et al. (49) found 90 min of hyperinsulinemic euglycemia to be associated with statistically significant increments in arterial plasma epinephrine concentrations. However, the increments were small (from 240 ± 40 to 340 ± 50 pmol/l); the stimulated levels were probably not high enough to exert biological effects (12, 13).

Plasma epinephrine concentrations (and forearm blood flows) did not change during hyperinsulinemic euglycemia but increased substantially during hyperinsulinemic hypoglycemia. Clearly, hypoglycemia per se stimulates adrenomedullary activity. Despite an apparent stepwise increase from the T1 (saline) to the T2 (hyperinsulinemia euglycemia) to the T3 (hyperinsulinemic hypoglycemia) time segments in the euglycemic to hypoglycemic limb, increments in plasma NE concentrations from T1 to T3 (ANOVA, P = 0.11) and from T2 to T3 (ANOVA, P = 0.05) were not significantly greater than those in the euglycemic limb. Similarly, despite an apparent stepwise increase from the T1 to the T2 to the T3 time segments in the euglycemic to hypoglycemic limb, increments in SNESO from T1 to T3 were not significantly greater than those in the euglycemic limb (ANOVA, P = 0.14), although the increments from T2 to T3 were significantly greater (ANOVA, P < 0.05). Although the latter finding suggests greater NE release during hyperinsulinemic hypoglycemia than during comparably hyperinsulinemic euglycemia, it does not identify the source. Given substantial adrenomedullary stimulation, evidenced by a ninefold increase in plasma epinephrine concentrations, it is conceivable that the additional NE was derived from the adrenal medullas. The forearm NE spillover data are consistent with that interpretation. Neither the absolute values nor the increments in FNESO were greater in the euglycemic to hypoglycemic limb than in the euglycemic limb. Thus the present data do not provide direct support for the concept that hypoglycemia per se also stimulates the sympathetic neural component of the sympathochromaffin system. As in study 1, there was considerable scatter in the forearm NE spillover data in study 2. That, and our small samples sizes, might have obscured differences between the magnitude of the responses to hyperinsulinemic hypoglycemia and euglycemia. Nonetheless, although the present data do not exclude the possibility that hypoglycemia per se stimulates sympathetic neural activity in sites other than the forearm, they are consistent with the possibility that hypoglycemia per se stimulates the adrenal medullas and not the sympathetic nervous system.

To our knowledge, all studies of sympathetic neural responses to hypoglycemia have employed insulin-induced hypoglycemia and are, therefore, potentially confounded by insulin-stimulated sympathetic neural activity. We are not aware of published studies, using microeurography, regional NE spillover, or microdialysis to measure sympathetic neural activity separately from adrenomedulary activity, that have contrasted sympathetic neural activity during hyperinsulinemic euglycemia and hyperinsulinemic hypoglycemia over the same time frame as was done in the present study. However, using microneurography, Frandsen et al. (19) found increments in muscle sympathetic nerve activity during hyperinsulinemic euglycemic clamps and further increments during subsequent hypoglycemic clamps at the same insulin infusion rate in healthy human subjects.

Hyperinsulinemia per se lowered plasma C-peptide and glucagon levels, raised blood lactate levels, and suppressed nonesterified fatty acid levels. Hyperinsulinemic hypoglycemia lowered plasma C-peptide levels further and raised plasma glucagon, epinephrine, NE, pancreatic polypeptide, growth hormone and cortisol levels, and SNESO and FNESO. Despite adrenomedullary activation and increased growth hormone and cortisol secretion, serum nonesterified fatty acid levels remained suppressed, an effect attributable to the potent antilipolytic action of ongoing hyperinsulinemia and the relatively short duration of activation of these lipolytic factors.

Although it is a simple and often useful index, the plasma NE concentration is a fallible index of sympathetic neural activity because circulating NE can be derived from sympathetic nerve terminals, the adrenal medullas, or both and because of regional differences in sympathetic neural activity under various conditions. Albeit in the uncommon circumstance of prolonged standing, the present data indicate that increments in plasma NE concentrations (and SNESO) can be dissociated from sympathetic neural activity in one region, the forearm, as assessed by the FNESO. Furthermore, the present data confirm that hyperinsulinemia per se stimulates sympathetic neural activity (1, 2, 4, 5, 9, 29, 39, 47, 50, 55), here assessed with the FNESO, without stimulating adrenomedullary activity, an issue that is still debated (33). Finally, although they confirm that hypoglycemia per se activates adrenomedullary activity (45), the present data do not provide direct support for the concept that hypoglycemia per se stimulates sympathetic neural activity (3, 4, 17, 31). Increments in forearm NE spillover during hyperinsulinemic hypoglycemia were not significantly greater than those during hyperinsulinemic euglycemia.

    ACKNOWLEDGEMENTS

We acknowledge the technical assistance of Krishan Jethi, Mary Hamilton, Joy Brothers, Carolyn Fritsche, and Zina Lubovich, the assistance of the nursing staff of the Washington University General Clinical Research Center, and the assistance of Kay Kerwin in the preparation of this manuscript.

    FOOTNOTES

This work was supported, in part, by National Institutes of Health Grants R01 DK-27085, M01 RR-00036, P60 DK-20579, and T32 DK-07120 and by a fellowship grant from the American Diabetes Association.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.

Address for reprint requests: P. E. Cryer, Campus Box 8127, Washington Univ. School of Medicine, 660 South Euclid Ave., St. Louis, MO 63110.

Received 11 March 1998; accepted in final form 28 July 1998.

    REFERENCES
Top
Abstract
Introduction
Methods
Results
Discussion
References

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