Pancreatic {beta}-Cell Function and Immune Responses to Insulin After Administration of Intranasal Insulin to Humans At Risk for Type 1 Diabetes

doi:10.2337/diacare.27.10.2348

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Emerging Treatments and Technologies
Original Article

Pancreatic ß-Cell Function and Immune Responses to Insulin After Administration of Intranasal Insulin to Humans At Risk for Type 1 Diabetes

Leonard C. Harrison, MD, DSC¹, Margo C. Honeyman, PHD¹, Cheryl E. Steele, RN¹, Natalie L. Stone, BSC¹, Elena Sarugeri, PHD², Ezio Bonifacio, PHD², Jennifer J. Couper, MD³ and Peter G. Colman, MD⁴

¹ Autoimmunity and Transplantation Division, The Walter and Eliza Hall Institute of Medical Research, Victoria, Australia
² Department of Internal Medicine, Istituto Scientifico San Raffaele, Milan, Italy
³ Department of Endocrinology, Women’s and Children’s Hospital, Adelaide, Australia
⁴ Department of Diabetes and Endocrinology, the Royal Melbourne Hospital, Victoria, Australia

Address correspondence and reprint requests to Leonard C. Harrison, The WalterEliza Hall Institute of Medical Research, 1G Royal Parade, Parkville 3050, Victoria, Australia. E-mail: harrison{at}wehi.edu.au

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
RESEARCH DESIGN AND METHODS
RESULTS
CONCLUSIONS
References

OBJECTIVE—Mucosal administration of insulin retards developmentof autoimmune diabetes in the nonobese diabetic mouse model.We conducted a double-blind crossover study in humans at riskfor type 1 diabetes to determine if intranasal insulin was safe,in particular did not accelerate ß-cell destruction,and could induce immune effects consistent with mucosal tolerance.

RESEARCH DESIGN AND METHODS—A total of 38 individuals,median age 10.8 years, with antibodies to one or more pancreaticislet antigens (insulin, GAD65, or tyrosine phosphatase-likeinsulinoma antigen 2) were randomized to treatment with intranasalinsulin (1.6 mg) or a carrier solution, daily for 10 days andthen 2 days a week for 6 months, before crossover. The primaryoutcome was ß-cell function measured as first-phaseinsulin response (FPIR) to intravenous glucose at 0, 6, and12 months and then yearly; the secondary outcome was immunityto islet antigens, measured monthly for 12 months.

RESULTS—No local or systemic adverse effects were observed.Diabetes developed in 12 participants with negligible ß-cellfunction at entry after a median of 1.1 year. Of the remaining26, the majority had antibodies to two or three islet antigensand FPIR greater than the first percentile at entry, as wellas ß-cell function that generally remained stableover a median follow-up of 3.0 years. Intranasal insulin wasassociated with an increase in antibody and a decrease in T-cellresponses to insulin.

CONCLUSIONS—Results from this pilot study suggest thatintranasal insulin does not accelerate loss of ß-cellfunction in individuals at risk for type 1 diabetes and inducesimmune changes consistent with mucosal tolerance to insulin.These findings justify a formal trial to determine if intranasalinsulin is immunotherapeutic and retards progression to clinicaldiabetes.

Abbreviations: Ab, antibody • DPT-1, Diabetes Prevention Trial–Type 1 • FPIR, first-phase insulin response • IA2, tyrosine phosphatase-like insulinoma antigen 2 • I/P, period 1 = I (insulin) and period 2 = P (placebo) • IQR, interquartile range • KLH, keyhole limpet hemocyanin • P/I, period 1 = P (placebo) and period 2 = I (insulin) • Th, T-helper

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
RESEARCH DESIGN AND METHODS
RESULTS
CONCLUSIONS
References

Type 1 diabetes is an autoimmune disease in which T-cells mediatedestruction of insulin-secreting ß-cells in the pancreaticislets. Asymptomatic individuals with preclinical type 1 diabetescan be identified by the presence of circulating antibodies(Abs) to insulin, GAD 65-kDa isoform, and tyrosine phosphatase-likeinsulinoma antigen 2 (IA2) (1–3). Insulin is the onlyself-antigen specific for ß-cells, and several linesof evidence indicate that it may play a major role in drivingautoimmune ß-cell destruction (4–7). In experimentalrodent models, administration of self-antigens to mucosa-associatedlymphoid tissues can induce immune tolerance and prevent autoimmunedisease (8,9). In the nonobese diabetic (NOD) mouse, a spontaneousmodel of autoimmune type 1 diabetes, oral (10) or naso-respiratory(11) insulin induces regulatory, diabetes-protective T-cells.After naso-respiratory insulin, there was a decrease in T-celland an increase in Ab responses to insulin (11), conformingto the shift from T-helper (Th)-1 cellular immunity to Th2 humoralimmunity that is associated with protection against diabetesin this rodent model (12). In human volunteers, oral (13) orintranasal (14) administration of the experimental antigen,keyhole limpet hemocyanin (KLH), induced similar shifts in T-celland Ab responses to KLH. Mucosa-mediated immune responses topotentially therapeutic self-antigens have not, however, beendocumented in humans.

Enthusiasm to translate therapeutic effects of mucosal tolerancefrom rodents to humans has been tempered by failure to demonstrateclinical benefit in the following trials of oral antigens: myelinbasic protein in multiple sclerosis (15), collagen in rheumatoidarthritis (16,17), and insulin in recently diagnosed (18,19)type 1 diabetes. These trials did not report evidence for animmune effect; therefore, it is not clear that the dose of oralantigen used was in fact immunogenic. A randomized trial oforal insulin completed in islet Ab–positive individualsat risk for type 1 diabetes was reported orally by Dr. Jay Skyler(Chairman, Diabetes Prevention Trial–Type 1 [DPT-1] StudyGroup) at the American Diabetes Association 63rd ScientificMeeting in 2003 but has not been formally published. Comparedwith the oral route, naso-respiratory administration has theadvantage that antigen is delivered directly in an undegradedform to the mucosa and in some cases has been shown to be moreeffective (20). Nevertheless, it is debatable whether mucosa-mediatedimmunoregulation would counteract pathogenic immunity in end-stageautoimmune disease, and the preferred candidates for such immunoregulatorytherapy are asymptomatic individuals with preclinical autoimmunedisease. Therefore, with the aim of establishing the potentialefficacy of mucosal antigen for preventing autoimmune disease,we conducted a randomized, double-blind, crossover study inindividuals at risk of type 1 diabetes to determine if intranasalinsulin was safe and could induce changes in immunity to insulinconsistent with mucosal tolerance. In the absence of absorption-promotingagents, intranasal insulin has no systemic metabolic effects(21–23). However, in regard to safety, it is necessaryto ensure that mucosal administration of insulin to individualsat risk for type 1 diabetes does not activate pathogenic immunityand accelerate ß-cell destruction.

RESEARCH DESIGN AND METHODS

TOP
ABSTRACT
INTRODUCTION
RESEARCH DESIGN AND METHODS
RESULTS
CONCLUSIONS
References

A total of 38 individuals at risk for type 1 diabetes (16 femalesand 22 males, median age 10.8 years) (Table 1) were recruitedby invitation from the Melbourne Pre-Diabetes Family Study (24),with informed consent and Human Ethics Committee approval. Allwere first-degree relatives of someone with type 1 diabetesand had circulating Abs to at least one of the following isletantigens: insulin, GAD65, or IA2. Of the participants, 4 hadone Ab, 22 had two Abs, and 12 had three Abs. The risk for type1 diabetes increases with the number of antigen specificities(1–3). All subjects were included in the intention-to-treatanalysis.

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Table 1— Characteristics of participants at entry and their status at follow-up, ordered by randomization

Treatment, assignment, and compliance
Humulin (a gift from Eli Lilly, Australia) or carrier solution(placebo) was transferred under sterile conditions into 15-mlbrown glass bottles (fitted with plastic pump spray nozzles)by the Clinical Trials Service, Pharmacy Department, Royal MelbourneHospital. Humulin contains pure recombinant human insulin at4 mg/ml in a carrier of water with 1.6 mg/ml glycerol and 0.25/mlm-cresol preservative. There is no evidence that either glycerolor m-cresol is immunogenic or alters immune responses. Randomizationfrom computer-generated numbers was performed in blocks of fourby the Clinical Trials Service. Two 100-µl spray dosesper nostril, equivalent to 20 units or 800 µg insulinper nostril (total 1.6 mg), were self-administered daily for10 consecutive days and then on each weekend day. Participantsand, if appropriate, their parent(s) were instructed in theuse of the nasal spray before the study, and their techniquewas checked during the study. The dose schedule was based onthe following considerations. In the NOD mouse, an antidiabeticeffect of aerosolized insulin was observed after daily administrationfor up to 10 days and then once or twice weekly (11). In adulthumans, Waldo et al. (14) found that 100 mg KLH in a 1-ml nasalspray given on four occasions 2 weeks apart increased Ab anddecreased T-cell proliferative responses to KLH. These investigatorssuggested that Ab sensitization might be avoided with a lowerdose. The concentration of insulin in commercially availablepreparations is fixed at 4 mg/ml, and there is a practical limitto the volume that can be administered intranasally, particularlyin children. We also reasoned that a lower spray volume witha proportionately lower dose of antigen would be delivered moreselectively to the naso-pharyngeal lymphoid tissue, which isrelatively rich in T-cells compared with B-cells, with lessspillover into the respiratory tract and esophagus. Finally,although each insulin dose was less than the dose of KLH usedby Waldo et al. (14), it was administered on more occasionsover a 6-month period. It was in an acceptable volume for children.Compliance was based on monthly interview and monitoring ofthe unused solution volume. Participants or their parents wereinstructed to report any symptoms and any local effect associatedwith spray use. They were also instructed to report any malfunctionor breakage of the spray bottle pump in order to receive animmediate replacement.

Outcome measures and study protocol
The primary objective was to determine if intranasal insulinwas safe and, in particular, did not accelerate ß-celldestruction as determined by serial measurement of first-phaseinsulin response (FPIR) to intravenous glucose. The secondaryobjective was to determine if intranasal insulin induced changesin immunity to insulin consistent with the induction of mucosaltolerance.

A crossover design (Fig. 1) was used to measure treatment effectas well as "period" and treatment "carry-over" (i.e., residual)effects. Participants were randomized to two arms (two 6-monthtreatment periods): in the I/P arm, period 1 = I (insulin) andperiod 2 = P (placebo); in the P/I arm, period 1 = P and period2 = I. This design allowed treatment effects to be measuredserially in the same individuals in a crossover comparison ofperiods 1 and 2, as well as between different individuals ina parallel across-arm comparison of insulin versus placebo inperiod 1.

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Figure 1— Study design protocol.

FPIR was measured at randomization and at 6 and 12 months. Afterthe initial visit, participants were seen monthly at visits1–6 in period 1 and visits 7–12 in period 2, whenvenous blood was taken for measurement of blood glucose; plasmainsulin, GAD65, and IA2 Abs; and T-cell proliferative responsesin the absence of antigen and in the presence of tetanus toxoidor denatured human insulin. Treatment was started at the initialvisit after blood sampling and crossed over after the month6 visit (Fig. 1). After completion of the 12-month study, participantswere followed regularly and, where possible, retested at leastyearly. The diagnosis of diabetes was based on American DiabetesAssociation criteria (25).

ß-Cell function
FPIR was measured as the sum of plasma insulin levels 1 and3 min after the intravenous injection of 0.5 g glucose/kg bodywt (26). Previously, we reported that when performed by a singleoperator as in this study, the within-subject reproducibilityof FPIR expressed as a mean coefficient of variation was 11.4%(range 5.2–19.2) (27,28). The first percentile cutofffor FPIR in healthy prepubescent children and young adults is $~$ 50 mU/l (29,30). The cutoff increases transiently to $~$ 75 mU/lin late puberty (Tanner stages IV-V). Insulin was measured withan IMX kit (Abbott Laboratories, Abbott Park, IL).

Immune parameters
Islet antibodies were measured by liquid-phase precipitationassays as previously described (1,2,24). The assays have hadoptimal sensitivity, specificity, validity, and consistencyin International Workshops and Standardization Programs conductedby the Immunology of Diabetes Society (e.g., the study by Vergeet al. [2]). The specificity and sensitivity of our assays inthe 2003 Diabetes Antibody Standardization Program were as follows:insulin Abs, 95 and 26%; GAD65 Abs, 97 and 80%; IA2 Abs, 100and 68%. The thresholds for positivity determined by receiveroperator characteristic analysis of 246 control subjects and135 patients with newly diagnosed type 1 diabetes were as follows:35 nU/ml insulin Abs, 5 units/ml GAD65 Abs, and 3 units/ml IA2Abs.

Proliferation of peripheral blood T-cells in the absence orpresence of tetanus toxoid (20 Lyons flocculating units/ml)or denatured human insulin (50 µg/ml) was measured ascounts per minute (cpm) ³H-thymidine uptake on samples collectedbetween 8:30 and 10:00 A.M., as previously described (31). Becausethe distribution of responses between replicates is not Gaussian,data were expressed as the medians of sextuplicates. Resultswere then expressed as a stimulation index, which is the ratioof median values in the presence and absence of antigen. Preservative-freetetanus toxoid (CSL, Melbourne, Australia) was used as a controlantigen. Hormonally active native insulin may suppress the functionof antigen-presenting cells or T-cells (32). Therefore, insulinwas denatured by heating a 1-mg/ml solution of human insulinin 0.01 mol/l HCl containing 100 mmol/l dithiothreitol at 90°Cfor 30 min, followed by dialysis against sterile PBS. The endotoxinconcentration in a 1-mg/ml solution of denatured insulin, measuredby Limulus lysate bioassay (BioWhittaker, Walkersville, MD),was <3 ng/ml.

Sample size and statistical analyses
There were no available data on the effect of intranasal insulinon metabolic or immune parameters in humans with which to estimatesample size. As an alternative, we used in-house measurementsof insulin Abs in newly diagnosed patients treated with subcutaneousinsulin. We estimated a sample size of 22 patients per groupfor a two-sided test at a power of 80% and a level of significanceof 5% to detect a 50% difference in the rate of change of insulinAbs (nU/ml per month). Given the lack of previous data on whichto base sample size and the crossover design of the study, theconsultant statistician’s advice was to perform a blindedinterim analysis after approximately half this number of participantshad completed the study. This analysis was performed independentlyby Dr. Jane Mathews, Statistical Centre, Peter MacCallum CancerInstitute, Melbourne.

Immune parameters were analyzed for two time periods: period1 after randomization and before crossover (monthly visits 1–6)and period 2 after crossover (monthly visits 7–12) (Fig. 1).In each period, parameters measured monthly in each participantwere summarized as follows: 1) the rate of change, or slope,derived from the linear regression of monthly values and 2)the median of the monthly values. Two comparisons were madeby nonparametric Mann-Whitney tests (two-tailed). First, a parallelacross-arm comparison of I (insulin) versus P (placebo) in period1 and, second, a comparison of periods 1 and 2 within each arm,for "treatment" (I vs. P), "period," and "carry-over" effects.The period effect was tested by comparing the difference ina parameter between periods 1 and 2 for participants randomizedto one arm with that between periods 2 and 1 for participantsrandomized to the other arm. A treatment carry-over effect wastested by comparing the difference between I and P in period1 with the difference between I and P in period 2, accordingto Jones and Kenward (33). Group results were expressed as themedian and interquartile range (IQR) and significance was takenas P < 0.05. The raw data are available on request.

RESULTS

TOP
ABSTRACT
INTRODUCTION
RESEARCH DESIGN AND METHODS
RESULTS
CONCLUSIONS
References

The characteristics at entry and status at follow-up of 20 participantsrandomized to the I/P arm and 18 to the P/I arm are tabulated(Table 1). No adverse local or general effects were reported.Most participants initially noted the odor of the spray (becauseof the preservative), but this did not affect compliance. Byinterview and spray bottle inspection, compliance was 100%.Four participants reported breakage of the plastic pump duringoperation on one to three occasions. In these cases, a replacementbottle pump was provided within 3 days, and that dose was repeated.A blinded interim analysis performed after 24 participants hadcompleted the 12-month study revealed no change in FPIR buta highly significant difference in insulin Abs between the twoperiods in each arm. Because there had been no change in ß-cellfunction but a difference in insulin Abs, the ethics committeeconsidered that the primary and secondary objectives had beenmet. A further 14 participants who had been entered by thisstage went on to complete the study, making a total of 38 participantsfinally analyzed.

ß-Cell function
A total of 12 participants, 6 randomized to either arm, developeddiabetes a median of 1.1 (range 0.33–3.6) years from entry.They were similar in age and number of islet Abs to the 26 whodid not develop diabetes and had similar changes in Ab and T-cellresponses to insulin (Fisher’s exact tests). However,their FPIR at entry was significantly lower than in those whodid not develop diabetes (median [IQR] 35.5 [19.0–42.5]vs. 98.5 [73.5–138] mU/l, P < 0.0001, Mann-Whitneytest). A total of 14 participants had an FPIR at entry lessthan or equal to the first percentile, and of these 11 developeddiabetes. Of the other 24 participants with an FPIR at entry>50 mU/l, only one with a borderline FPIR of 56 mU/l developeddiabetes. FPIR at entry was similar between the randomized groups.There was no difference in FPIR at entry and after 12 months(median 98.5 vs. 107 mU/l) in the 26 participants who did notdevelop diabetes (Fig. 2). An isolated fall in FPIR at 12 monthsin two participants was associated with documented hemolysisof the plasma samples, a condition known to artifactually lowerinsulin values in the assay. With yearly follow-up for a median3.0 years, FPIR was remeasured at least once in 21 of the individualswho remained nondiabetic (Fig. 2). Comparing the last measurementwith that at entry revealed no change in 12, an increase >50%in 6, and a decrease >50% in 3.

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Figure 2— ß-Cell function in study participants. FPIR measured at the start, crossover, and end of the study and during follow-up. Circles and squares denote, respectively, participants who remained diabetes-free or who developed diabetes. Closed symbols joined by solid lines are participants randomized to the I/P arm; open symbols joined by dotted lines are those randomized to the P/I arm.

Immune parameters
Administration of intranasal insulin was followed by an increasein circulating insulin Abs (Fig. 3). The increase in insulinAbs was associated with a decrease in T-cell responses to insulin,shown for the monthly rate of change or slope of these parametersfor each participant (Fig. 4). The difference in insulin Abs(nU · ml^–1 · month^–1) was highly significantfor the parallel arm comparison of insulin versus placebo inperiod 1 (median [IQR] 7.4 [1.7 to 35] vs. –6.3 [–22to 6.7], P = 0.003) and for the within-arm crossover comparisonsbetween the periods (I/P arm: 7.4 [1.7 to 35] vs. –6.8[–35 to 2.7], P = 0.004; P/I arm: –6.3 [–22to 6.7] vs. 26 [13 to 125]), P < 0.0001). There was no periodeffect, but the influence of intranasal insulin on insulin Abswas associated with a carry-over effect from the insulin intothe placebo period (P = 0.02). Similar findings were obtainedwhen, for each participant, the median of monthly values ineach 6-month period rather than the monthly rate of change ofinsulin Ab values was used for comparison (data not shown).

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Figure 3— Monthly insulin Abs (median for participants in either arm) during the study.

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Figure 4— Ab and T-cell responses to insulin in individual participants. The monthly rate of change of either insulin Ab (A) or the T-cell response to denatured insulin (B) was determined from serial measurements in each participant in the insulin (I)/placebo (P) and P/I arms. Dotted lines link each subject in the two treatment periods.

The maximum levels of insulin Abs after intranasal insulin,in relation to pretreatment levels, are summarized in Table 2.During period 1, 11 of 20 participants in the I/P arm comparedwith 2 of 18 participants in the P/I arm had an increase ininsulin Abs >100 nU/ml within 4 months of starting treatment.There were strong positive relationships between levels of insulinAbs in participants before and after intranasal insulin. Relatingthe median level in the placebo period with the correspondingmedian level in the insulin period of the P/I arm yielded acorrelation coefficient (r) of 0.79 (P = 0.0001, two-tailedSpearman test). The slope of this relationship by least squareslinear regression was 1.5, indicating that responses were proportionallystronger with increasing pretreatment levels of insulin (auto)Ab. There was also a significant correlation between the levelsof median insulin Ab in the insulin and placebo periods of theI/P arm (r = 0.94, P < 0.0001). The levels of GAD65 and IA2Abs did not change significantly throughout the study.

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Table 2— Maximum insulin Ab level (nU/ml) level after intranasal insulin

Basal T-cell proliferation in the absence of antigen was notdifferent for any of the comparisons. Thus, basal counts perminute (median cpm) expressed as the median (IQR) for each periodwere 778 (445–1,140) and 698 (485–1,326) for theI/P arm and 822 (502–1,289) and 908 (643–1,319)for the P/I arm. T-cell proliferation indexes to tetanus (cpmtetanus/cpm basal), expressed as monthly rates of change (I/Parm: –3.48 [–8.38 to 0.59] vs. –0.92 [–3.94to 3.03]; P/I arm: –6.00 [–7.91 to 0.305] vs. –1.18[–6.35 to 1.62]) or medians (data not shown) for eachperiod, were also similar in both arms.

T-cell proliferation indexes to insulin, expressed as monthlyrate of change (Fig. 4), were not significantly different inthe parallel arm comparison of insulin and placebo in the firstperiod (median [IQR]) (–0.28 [–0.91 to –0.02]vs. –0.03 [–0.27 to 0.18], P = 0.09). However, inthe within-arm crossover comparisons, intranasal insulin wasassociated with significant decreases in T-cell proliferationto insulin (I/P arm: –0.28 [–0.9 to –0.02]vs. –0.09 [–0.14 to 0.33], P = 0.003; P/I arm: –0.03[–0.27 to 0.18] vs. –0.30 [–0.73 to 0.10],P = 0.02). There was no effect of period and no carry-over effect.Using the median of the monthly values in each 6-month period,T-cell proliferation to insulin during intranasal insulin wassignificantly decreased in the parallel arm comparison of insulinand placebo in period 1 (1.20 [0.79–2.13] vs. 1.85 [1.35–3.50],P = 0.03) and in the crossover comparison in the P/I arm (1.85[1.35–3.50] vs. 1.13 [0.65–1.60], P = 0.008). Therewas also a significant difference in the crossover comparisonin the I/P arm (1.20 [0.79–2.13] vs. 0.60 [0.33–0.88],P = 0.0006) associated with a carry-over effect of intranasalinsulin to suppress the T-cell response into the placebo period(P = 0.002). Again, there was no effect of period. No relationshipswere found between immune responses and HLA D locus–relatedstatus, FPIR, or diabetes development or between immune or metabolicresponses and insulin dose per kilogram.

CONCLUSIONS

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ABSTRACT
INTRODUCTION
RESEARCH DESIGN AND METHODS
RESULTS
CONCLUSIONS
References

Intranasal insulin was well tolerated and had no apparent adverseeffects. It was associated with an overall increase in Abs anda decrease in T-cell responses to insulin. The same immune changeswere observed after naso-respiratory insulin in NOD mice (11).In the only other studies in humans in which immune markerswere documented in response to mucosal antigen, oral (13) orintranasal (14) administration of the experimental antigen,KLH, similarly increased Ab and decreased T-cell responses toKLH. The changes we observed in participants were insulin specific,because no changes were detected in basal or tetanus toxoid–stimulatedT-cell responses or in Abs to GAD65 and IA2 after intranasalinsulin. The changes in immunity to insulin conform to the patternof Th1 to Th2 immune deviation that has been associated withmucosal tolerance (8,9) and with protection from diabetes inthe NOD mouse (12). Although the directions of the immune responsesto insulin were similar overall within treatment periods, therewere large interindividual differences and some exceptions (Fig. 4).The reasons are likely to be several. First, although therewas no apparent relationship between dose per kilogram and immuneor metabolic effects, the possibility that responses were doserelated cannot be excluded and would need to be addressed bydose-ranging studies. Second, although all participants appearedto be compliant, variations in the technique of administeringnasal insulin could lead to differences in bioavailability andconsequent immune responses. Third, there is likely to be geneticheterogeneity in priming to insulin as an autoantigen, as suggestedby our finding of a strong correlation between pretreatmentinsulin (auto) Ab levels and the insulin Ab response to intranasalinsulin. Although we found no association with specific HLAalleles in this study, insulin immunity may be controlled byother genetic loci, for example, IDDM2, which appears to regulatethe level of proinsulin gene transcription in the thymus andtherefore in all likelihood the degree of immune tolerance toinsulin (34). A further factor in relation to the T-cell studiesis the well-recognized difficulty of detecting responses toinsulin and other islet antigens with sensitivity and precision(35). For the in vitro T-cell studies, we used denatured insulinto avoid a possible effect of the hormone to suppress immunefunction (32) and an assay protocol that allowed us previouslyto demonstrate proliferation to islet antigen peptide epitopes(31). However, the magnitude of the responses was low, underscoringthe need for improved means of assaying antigen-specific T-cells.There were discrepancies between results for the parallel armand carry-over analyses depending on whether monthly rates ofchange or medians for each period were used, but the crossoveranalyses with either parameter were consistent in showing thatT-cell proliferation to insulin varied according to treatmentperiod.

Insulin auto-Abs are a risk marker for type 1 diabetes (1–3)and the increase in insulin Abs after intranasal insulin raisesconcern that this treatment might accelerate diabetes development.However, an increase in insulin Abs was not associated withdeterioration of ß-cell function in the 24 participantswith an FPIR greater than the first percentile at entry, excludingthe 1 with a borderline FPIR of 56 mU/l who developed diabetesduring the study. On the contrary, the remarkable stabilityof FPIR on follow-up in these participants, most of whom hadAbs to at least two islet antigens and were therefore at significantrisk (1–3), contrasts with the decline in FPIR over asimilar period that we have observed in comparable individualsfrom the Melbourne Pre-Diabetes Family Study (24; L.C.H., P.G.C.,unpublished data). Furthermore, in the recently reported DPT-1,a trial of oral insulin in islet Ab–positive relativeswith FPIR greater than the first percentile, the observed andpredicted progression to diabetes over 5 years in the control(and treated) groups was 36% (J. Skyler, personal communication).All participants in the current study received treatment withintranasal insulin for 6 months, and the study was not designedto answer whether intranasal insulin could prevent developmentof clinical diabetes. However, on the basis of our own and other(36) natural history studies, and the findings of DPT-1, wewere surprised that only one of the participants with Abs totwo or three islet antigens and FPIR greater than the firstpercentile progressed to diabetes during follow-up. Individualswho did develop diabetes had similar immune profiles to thosewho remained asymptomatic but were distinguished by very lowFPIR at entry, which is a recognized antecedent of symptomaticdisease (37,38).

Trials of oral insulin in individuals with recently diagnosedtype 1 diabetes (18,19) showed no apparent clinical benefitbut did not report treatment effects on surrogate markers ofpotential efficacy. Therefore, it is not possible to know iforal insulin was bioavailable and immunogenic at the level ofthe mucosa. We chose to evaluate the nasal delivery becauseit has several potential advantages over the oral route. Insulinis delivered in an undegraded form directly to the naso-pharyngealmucosa, whereas oral insulin is subject to degradation in thestomach. Possibly related to this is the fact that the doseof nasal insulin required to induce regulatory T-cells and protectagainst diabetes development in the NOD mouse (11) is lowerthan that of oral insulin (10) and therefore may be more readilyextrapolated to humans. In addition, immune tolerance has beenobserved after nasal but not oral delivery of the identicalpeptide (20). We found that intranasal insulin induced immuneeffects but had no apparent effect to accelerate diabetes development.This is, to our knowledge, the first demonstration in humansof an effect of mucosally administered autoantigen on potentialsurrogate disease markers. Although these immune effects areconsistent with the induction of mucosal tolerance and are inaccord with the literature (11,13,14), they do not constituteproof of immune tolerance to insulin. The ultimate demonstrationof this in humans would be the ability of intranasal insulinto prevent or delay diabetes onset. We propose that the presentstudy provides a rationale to determine in a formal trial whetherintranasal insulin is immunotherapeutic and retards ß-celldestruction and progression to clinical diabetes.

Acknowledgments

The study was supported by VicHealth and by the Juvenile DiabetesResearch Foundation. The insulin and carrier solution were donatedby Eli Lilly, Australia.

We thank Lorraine Fong, Sue Ewart, and Angela Morris, PharmacyDepartment, Royal Melbourne Hospital, for randomization, formulation,and dispensing; Matthew Wright for technical assistance; andDr. Anne-Louise Ponsonby for critical comments on the manuscript.

Footnotes

A table elsewhere in this issue shows conventional and SystèmeInternational (SI) units and conversion factors for many substances.

Received for publication January 22, 2004. Accepted for publication July 9, 2004.

References

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ABSTRACT
INTRODUCTION
RESEARCH DESIGN AND METHODS
RESULTS
CONCLUSIONS
References

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