Laboratory investigations of the survivability of bacteria in hypervelocity impacts.

It is now well established that material naturally moves around the Solar System, even from planetary surface to planetary surface. Accordingly, the idea that life is distributed throughout space and did not necessarily originate on the Earth but migrated here from elsewhere (Panspermia) is increasingly deemed worthy of consideration. If life arrived at the Earth from space, its relative speed will typically be of order many km s-1, and the resulting collision with the Earth and its atmosphere will be in the hypervelocity regime. A mechanism for the bacteria to survive such an impact is required. Therefore a programme of hypervelocity impacts in the laboratory at (4.5 +/- 0.6) km s-1 was carried out using bacteria (Rhodococcus) laden projectiles. After impacts on a variety of target materials (rock, glass and metal) attempts were made to culture Rhodococcus from the surface of the resulting craters and also from the target material ejected during crater formation. Control shots with clean projectiles yielded no evidence for Rhodococcus growth from any crater surface or ejecta. When projectiles doped with Rhodococcus were used no impact crater surface yielded colonies of Rhodococcus. However, for four shots of bacteria into rock (two on chalk and two on granite) the ejecta was afterwards found to give colonies of Rhodococcus. This was not true for shots onto glass. In addition, shots into aerogel (density 96 kg m-3) were also carried out (two with clean projectiles and two with projectiles with Rhodococcus). This crudely simulated aero-capture in a planetary atmosphere. No evidence for Rhodococcus growth was found from the projectiles captured in the aerogel from any of the four shots.

Improving insulin therapy: achievements and challenges.

Microvascular complications of diabetes can be forestalled by effective glycemic control. However, the inherent limitations of standard subcutaneous insulins reduce their ability to control glycemia without risk of significant hypoglycemia and hyperinsulinemia. Hypoglycemia is unacceptable for most patients and may be dangerous. Hyperinsulinemia is undesirable because it causes weight gain and it has a putative association with atherosclerosis. This paper summarizes the major historical improvements in insulin therapy, and calls attention to the fact that none of the presently available commercial preparations in any combination is capable of simulating the profile of normal insulin secretion--the latter being regarded as the most effective means of normalizing glycemia. For this reason, a variety of new approaches to simulating the pharmacokinetics or glucodynamics of insulin secretion are under investigation. Fast-acting insulin analogues suitable for subcutaneous injection have been developed and appear to mimic the physiological insulin response more closely than standard insulins. Less progress has been made with basal insulins. Intravenous insulin has pharmacodynamic advantages but practical disadvantages of administration. Nasal insulin would be an attractive treatment modality only if its bioavailability could be significantly increased and its safety assured. Other interventions which improve glucose metabolism without necessarily simulating normal insulin secretion are under investigation. These include biosynthetic human C-peptide, insulin-like growth factor-1 and glucagon-like peptide 1 (7-36 amide).

New directions in drug development: mixtures, analogues, and modeling.

Success in modern medical research is achieved when basic and clinical information about a given disorder converges, either intentionally or fortuitously, with the availability of technology or other means to design and apply interventions for the disorder in question. A prime example is the discovery of insulin and its replacement in patients with IDDM in 1923. Seven decades later, the focus of diabetes management is on improvement in metabolic control to forestall the chronic complications of the disease and improve the quality of life of patients with the disease. Metabolic control is being addressed through the development of insulin analogues using sophisticated techniques to understand the chemistry of insulin and to modify it using rDNA technology. The objective of these efforts is to simulate normal insulin secretion with subcutaneously injected agonists. Quality-of-life needs are being addressed with delivery devices, insulin mixtures, and insulin analogues. Although none of these improvements parallel the discovery of insulin, they do provide an optimistic outlook for patients with diabetes mellitus.

Biosynthetic human proinsulin. Review of chemistry, in vitro and in vivo receptor binding, animal and human pharmacology studies, and clinical trial experience.

OBJECTIVE: To describe the rationale for the preclinical and clinical developmental course of human proinsulin (HPI), the second product after human insulin for the treatment of diabetes mellitus to be manufactured by DNA technology. RESEARCH DESIGN AND METHODS: The relevant and available published and unpublished preclinical and clinical information generated on pork proinsulin and human proinsulin has been integrated to demonstrate how certain clinically attractive features of pork proinsulin (a soluble intermediate-acting and possibly hepatospecific insulin agonist) led to the development of HPI. RESULTS: Clinical pharmacology studies demonstrated that HPI was definitely, although marginally, hepatospecific. More striking was the finding that the intrasubject/patient coefficient of variation of response to HPI was significantly less than that observed with NPH insulin. However, the fact that unique efficacy in controlled multicenter studies was not demonstrated suggested that these pharmacological features were not translated into clinical benefit. In one multicenter new patient study there were six myocardial infarctions, including two deaths, in patients treated for greater than or equal to 1 yr with HPI and none in the control group. CONCLUSIONS: To obtain an independent review of the risks and benefits of HPI, in February 1988, Lilly convened a consultant group that examined all relevant information on HPI available. These experts shared our concerns about the safety of HPI in light of the failure to demonstrate unique efficacy. Accordingly, clinical trials with HPI were suspended in February 1988. Experience with HPI demonstrates the challenge associated with the development of new drugs in general and insulin agonists in particular.

Immunological and metabolic responses of patients with history of antibody-induced beef insulin resistance to treatment with beef, pork, human, and sulfated beef insulin.

OBJECTIVE: We evaluated immunological and metabolic responses during therapy with beef (B), pork (P), human (H, rDNA), and sulfated beef (SB) insulins in patients with insulin-antibody-mediated insulin resistance. RESEARCH DESIGN AND METHODS: A randomized double-blind sequential crossover study was performed with each insulin administered for 56 days unless dose reached 200 U/day or allergy developed. Participants were 26 individuals with history of B-P insulin dosage greater than or equal to 200 U/day and insulin binding capacities greater than 0.216 nM (30 mU/ml serum). Twenty-one participants completed the study. Insulin dosage/day, fasting plasma glucose, percentage HbA1, insulin antibody binding capacity (IABC), bound insulin (BI), percentage binding of 125I-labeled B, P, and H insulins, and receptor inhibition factor (RIF) were assessed. RESULTS: Mean insulin dosage (U/day) was significantly greater on B (88.9) than on P (29.2), H (29.4), or SB (29.6). On B, dosage increased in 12 individuals and reached 200 U/day in 6 individuals. Mean fasting plasma glucose (12.1 mM) and HbA1 (11%) were significantly higher on B than on P, H, and SB. Mean IABC, bound insulin, RIF, and percentage of B, P, and H bound were significantly higher on B than on P, H, and SB. Prolonged treatment with SB before entry into the study (greater than 5 wk) resulted in a blunted anamnestic response to B insulin. CONCLUSIONS: Rechallenge with B results in anamnestic immunological response and deterioration of metabolic control. SB, H, and P insulins have equivalent effects in patients with insulin antibody-mediated immunologic resistance.

Treatment of NIDDM with insulin agonists or substitutes.

Non-insulin-dependent diabetes mellitus (NIDDM) is a common disorder occurring in 3-6% of adults in most western populations. In the United States, 29% of patients with diabetes take insulin; of these, 76% have NIDDM. Insulin therapy is usually required at some time in NIDDM. Insulin therapy improves the abnormalities of NIDDM (reduced beta-cell function, increased hepatic glucose production, reduced peripheral glucose disposal, lipid abnormalities). Insulin and sulfonylurea agents have comparable effects on mild forms of NIDDM, but for more severe forms, insulin is usually superior. Combination insulin-sulfonylurea treatment may improve the response to sulfonylureas, although long-term well-controlled trials have not been conducted. Short-term insulin treatment may restore response to sulfonylureas. Other promising treatments (human proinsulin, nasal insulin, somatostatin) have not shown any advantage over conventional insulin therapy. Insulin causes hypoglycemia and peripheral hyperinsulinemia. The hazards of hyperinsulinemia, e.g., weight gain and hypoglycemia, have been overstated, and questions about its atherogenic effects remain to be resolved. The effect of glycemic control on macro- and microvascular complications has not been established; however, maintaining fasting blood glucose levels of less than 6.7 mM may protect against progression of retinopathy, neuropathy, and nephropathy and reduce the severity of ischemic stroke. Dosage algorithms generally use intermediate- or long-acting insulin to control basal glycemia, with regular insulin added before meals if needed to control postprandial glycemia. Effective therapy depends on the patient being informed, cooperative, and willing to self-monitor blood glucose. Insulin treatment intermittency increases the risk for immune complications (resistance and allergy). Overall, patients with NIDDM can benefit from insulin therapy.

Reduction of insulin clearance during hyperglycemic clamp. Dose-response study in normal humans.

Insulin secretion and clearance were studied in eight normal subjects who underwent hyperglycemic clamp studies at plasma glucose levels of 120, 225, and 300 mg/dl on three occasions. Insulin secretion rates were calculated during a 1-h baseline period and during 3 h of glucose clamping from a two-compartmental analysis of peripheral C-peptide concentrations with individual kinetic parameters derived after intravenous bolus injections of biosynthetic human C-peptide. At the 300-mg/dl clamp level, the insulin secretion rate increased to a value 9.9 +/- 0.7 times that of basal at the end of the clamp (mean +/- SE), whereas over the same period, the peripheral insulin concentrations increased to a greater extent, reaching a value 15.4 +/- 1.2 times that of basal (P = .002). This greater relative increase in the insulin concentration in comparison with the corresponding insulin secretion rate suggests a reduction in the clearance of endogenous insulin. A similar trend was seen at the 225-mg/dl clamp level, but the relative increase in the insulin concentration (9.9 +/- 1.5 times that of basal) was not significantly higher than the relative increase in the insulin secretion rate (8.1 +/- 0.5 times that of basal, P = .17). At the 120-mg/dl clamp level, the relative increases in the insulin secretion rate (2.7 +/- 0.2 times that of basal) and the insulin concentration (2.4 +/- 0.2 times that of basal) were similar (P = .26), indicating no reduction in endogenous insulin clearance during moderate stimulation of insulin secretion. In conclusion, a reduction in endogenous insulin clearance occurs during greater stimulation of insulin secretion at higher glucose-clamp levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Reevaluation of urine C-peptide as measure of insulin secretion.

Urine C-peptide (UCP) has been proposed as a measure of insulin secretion, because insulin and C-peptide are consecreted in equimolar concentrations by the pancreatic beta-cell. The validity of this approach was tested by comparing insulin secretion rates, calculated by application of a two-compartmental analysis of peripheral C-peptide concentrations, with UCP excretion rates. Insulin secretion and UCP excretion with subjects on a mixed diet were simultaneously measured over a 24-h period in 13 patients with noninsulin-dependent diabetes mellitus and in 14 matched nondiabetic control subjects. The fraction of secreted C-peptide that was excreted in the urine (fractional C-peptide excretion) showed considerable intersubject variability in the diabetic (11.3 +/- 1.6%, range 3.9-20.8) and control (8.0 +/- 1.7%, range 1.1-27.9, P = .07) subjects (means +/- SE). UCP clearance demonstrated a similar degree of variability and was not significantly different (P = .07) between diabetic (23.8 +/- 3.0 ml/min) and control (16.5 +/- 2.7 ml/min) subjects. In control subjects, the 24-h insulin secretion rate correlated more closely with the fasting insulin secretion rate (r = .97, P = .0001), fasting C-peptide (r = .81, P = .0005), and fasting insulin (r = .80, P = .0005) concentrations than with the 24-h UCP excretion rate (r = .62, P = .02). Similar results were obtained in the diabetic patients.(ABSTRACT TRUNCATED AT 250 WORDS)

Abnormal patterns of insulin secretion in non-insulin-dependent diabetes mellitus.

To determine whether non-insulin-dependent diabetes is associated with specific alterations in the pattern of insulin secretion, we studied 16 patients with untreated diabetes and 14 matched controls. The rates of insulin secretion were calculated from measurements of peripheral C-peptide in blood samples taken at 15- to 20-minute intervals during a 24-hour period in which the subjects ate three mixed meals. Incremental responses of insulin secretion to meals were significantly lower in the diabetic patients (P less than 0.005), and the increases and decreases in insulin secretion after meals were more sluggish. These disruptions in secretory response were more marked after dinner than after breakfast, and a clear secretory response to dinner often could not be identified. Both the control and diabetic subjects secreted insulin in a series of discrete pulses. In the controls, a total of seven to eight pulses were identified in the period from 9 a.m. to 11 p.m., including the three post-meal periods (an average frequency of one pulse per 105 to 120 minutes), and two to four pulses were identified in the remaining 10 hours. The number of pulses in the patients and controls did not differ significantly. However, in the patients, the pulses after meals had a smaller amplitude (P less than 0.03) and were less frequently concomitant with a glucose pulse (54.7 +/- 4.9 vs. 82.2 +/- 5.0, P less than 0.001). Pulses also appeared less regularly in the patients. During glucose clamping to produce hyperglycemia (glucose level, 16.7 mmol per liter [300 mg per deciliter]), the diabetic subjects secreted, on the average, 70 percent less insulin than matched controls (P less than 0.001). These data suggest that profound alterations in the amount and temporal organization of stimulated insulin secretion may be important in the pathophysiology of beta-cell dysfunction in diabetes.

Dose-dependent effects of oral and intravenous glucose on insulin secretion and clearance in normal humans.

Insulin secretion and clearance were studied in 2 groups of 7 normal subjects who each received 25, 50, and 100 g of glucose either orally or intravenously (iv) on separate occasions. Insulin secretion rates were calculated during a 1-h base line and for 5 h after glucose administration from a two-compartmental analysis of peripheral C-peptide concentrations using individual kinetic parameters derived after iv bolus injections of biosynthetic human C-peptide. Incremental glucose areas after oral or iv glucose increased as a function of the glucose dose (P = 0.0001). Incremental insulin secretion increased with increasing doses of both oral and iv glucose (P = 0.0001). The metabolic clearance rate (MCR) of endogenous insulin was calculated as the ratio of the total area under the insulin secretion rate curve and the simultaneous peripheral insulin concentration curve. The basal MCR was 1,879.5 +/- 110.5 ml/min (mean +/- SE). The poststimulatory MCR decreased with increasing doses of both oral and iv glucose concomitant with the greater insulin secretory response (P = 0.0014). This decrease in insulin clearance was not significantly different between oral and iv administration of glucose (P = 0.495). In conclusion diminished insulin clearance may be seen after marked stimulation of insulin secretion with larger doses of oral and iv glucose.

Immunologic aspects of human proinsulin therapy.

We investigated the immunogenicity of human proinsulin (HPI) when used as the sole or principal insulin agonist in insulin-naive patients with insulin-dependent (type I) and non-insulin-dependent (type II) diabetes mellitus. Sixty-one patients (13 type I, 48 type II) were treated with rDNA human insulin (NPH HI with or without regular HI) and 53 were treated with HPI (8 type I, 45 type II). At 6 mo, virtually identical levels of HbA1c (5.2 vs. 5.3%, P = NS) were achieved. However, regular HI was added less often to the treatment regimen in HPI-treated patients (16 vs. 32 patients, P less than .001). Overall, there was no significant increase in proinsulin-specific antibodies in either treatment group. However, 8 of 51 (1 transiently) patients in the HPI group developed low levels of binding of HPI (highest percentage bound was 5%). Two patients in the HI group developed very low levels of HPI binding (1.2 and 1.9%). Binding of HI (greater than 2.4%) was seen in both treatment groups; however, the prevalence of HI binding was less in the HPI group at 6 mo (39 of 60 in HI group vs. 20 of 51 in HPI group, P = .008). Concomitant treatment with regular HI did not affect the prevalence or level of binding of HPI or HI. We conclude that human proinsulin is a weak immunogen when used as the principal insulin agonist and may reduce both the formation of anti-HI antibodies and the need for concomitant therapy with regular HI.

Quantitative study of insulin secretion and clearance in normal and obese subjects.

The secretion and hepatic extraction of insulin were compared in 14 normal volunteers and 15 obese subjects using a previously validated mathematical model of insulin secretion and rate constants for C-peptide derived from analysis of individual decay curves after intravenous bolus injections of biosynthetic human C-peptide. Insulin secretion rates were substantially higher than normal in the obese subjects after an overnight fast (86.7 +/- 7.1 vs. 50.9 +/- 4.8 pmol/m2 per min, P less than 0.001, mean +/- SEM), over a 24-h period on a mixed diet (279.6 +/- 24.2 vs. 145.8 +/- 8.8 nmol/m2 per 24 h, P less than 0.001), and during a hyperglycemic intravenous glucose infusion (102.2 +/- 10.8 vs. 57.2 +/- 2.8 nmol/m2 per 180 min, P less than 0.001). Linear regression analysis revealed a highly significant relationship between insulin secretion and body mass index. Basal hepatic insulin extraction was not significantly different in the normal and obese subjects (53.1 +/- 3.8 vs. 51.6 +/- 4.0%). In the normal subjects, fasting insulin did not correlate with basal hepatic insulin extraction, but a significant negative correlation between fasting insulin and hepatic insulin extraction was seen in obesity (r = -0.63, P less than 0.02). This finding reflected a higher extraction in the six obese subjects with fasting insulin levels within the range of the normal subjects than in the nine subjects with elevated fasting insulin concentrations (61 +/- 3 vs. 45 +/- 6%, P less than 0.05). During the hyperglycemic clamp, the insulin secretion rate increased to an average maximum of 6.2-fold over baseline in the normal subjects and 5.8-fold in the obese subjects. Over the same time, the peripheral insulin concentration increased 14.1-fold over baseline in the normals and 16.6-fold over baseline in the obese, indicating a reduction in the clearance of endogenously secreted insulin. Although the fall in insulin clearance tended to be greater in the obese subjects, the differences between the two groups were not statistically significant. Thus, under basal, fasting conditions and during ingestion of a mixed diet, the hyperinsulinemia of obesity results predominantly from increased insulin secretion. In patients with more marked basal hyperinsulinemia and during intense stimulation of insulin secretion, a reduction in insulin clearance may contribute to the greater increase in peripheral insulin concentrations that are characteristic of the obese state.+

Insulin secretion and clearance. Comparison after oral and intravenous glucose.

Insulin secretion and clearance in response to the administration of oral and intravenous glucose was investigated in nine normal men. C-peptide metabolic kinetics were calculated by analysis of individual C-peptide decay curves after the bolus injection of biosynthetic human C-peptide. Glucose was administered to the subjects on three occasions: as a 75-g oral dose, a 75-g i.v. infusion, and an intravenous glucose infusion at a variable rate adjusted to mimic the peripheral glucose levels obtained after the oral glucose load (matching experiment). Glucose, insulin, and C-peptide concentrations were measured for the subsequent 5 h. The glucose level after the oral glucose load (115.9 +/- 2.6 mg/dl, mean +/- SE) closely approximated that after the matching experiment (120.5 +/- 2.5 mg/dl) but was significantly lower than after 75 g i.v. glucose (127.7 +/- 3.4 mg/dl, P less than .05). Analysis of the areas under the peripheral concentration curves (60-360 min) showed that the responses of both insulin (52.7 +/- 5.6 and 46.5 +/- 4.5 pmol.ml-1.300 min-1) and C-peptide (252.7 +/- 27.5 and 267.0 +/- 21.6 pmol.ml-1.300 min-1) were not significantly different after the oral and 75-g i.v. glucose studies, respectively, whereas in the matching experiment, both the insulin (26.1 +/- 3.9 pmol.ml-1.300 min-1) and C-peptide (178.0 +/- 18.9 pmol.ml-1.300 min-1) responses were lower (P less than .05) than in the other two studies. Insulin secretory rates were derived from peripheral C-peptide concentrations with an open two-compartment model and individually derived model parameters. (ABSTRACT TRUNCATED AT 250 WORDS)

The effect of biosynthetic human proinsulin on the hepatic response to glucagon in insulin-deficient diabetes.

The relative tissue specificities of biosynthetic human proinsulin and porcine insulin were compared in eight insulin-deficient diabetic patients. Variable proinsulin and insulin infusions were administered iv for at least 18 h on separate occasions to achieve euglycemia. Once equivalence with respect to this end point was established, the paired infusions were made constant and compared with respect to their effect on plasma glucose, hepatic glucose output (Ra), glucose utilization, glucose clearance, and blood beta-hydroxybutyrate, alanine, and glycerol in response to a glucagon infusion (3 ng/kg X min). Basal Ra did not differ between euglycemia established using proinsulin vs. insulin [1.92 +/- 0.12 vs. 1.65 +/- 0.07 mg/kg X min] when data were analyzed by multivariate analysis of variance; likewise, the increment in Ra in response to glucagon infusion did not differ between the two treatments (1.26 +/- 0.22 vs. 1.17 +/- 0.24 mg/kg X min). Blood beta OHB, alanine, and glycerol also did not differ between the insulin and proinsulin treatments. Under these conditions of prolonged infusion in which the differences in clearance properties between proinsulin and insulin do not play a role and which maintain basal euglycemia, the two compounds equally limit the response to a stimulus to hepatic glucose production. Under nonsteady state conditions, when the differences in clearance rates are operative, proinsulin may have relatively greater effects on Ra than do doses of insulin that are biologically equivalent after prolonged infusions.

The effects of biosynthetic human proinsulin on carbohydrate metabolism in non-insulin-dependent diabetes mellitus.

We compared the glucose-lowering effect of proinsulin, the precursor molecule of insulin, with that of insulin itself. In patients with non-insulin-dependent diabetes mellitus (NIDDM) in whom proinsulin (0.2 U per kilogram of body weight) was subcutaneously injected at 9 a.m., fasting glucose levels (247 +/- 22 mg per deciliter [+/- SEM]) became normal within six hours and elevated rates of hepatic glucose output were lowered. The response to regular insulin (0.2 U per kilogram) was of similar magnitude but faster. Glucose clearance was stimulated less by proinsulin, reflecting its preferential action in suppressing glucose output. Hypoglycemia occurred in five of nine insulin-treated patients, but in only one of nine proinsulin-treated patients. After proinsulin injection at bedtime (30.5 +/- 4 U), serum proinsulin concentrations reached a peak by five hours and declined gradually thereafter. Fasting hepatic glucose output became normal, and euglycemia was sustained without overnight hypoglycemia. Proinsulin reduced plasma glucose more effectively than an equal unit dosage of NPH insulin, but since higher doses of NPH insulin were not used, no conclusions could be drawn about the relative desirability of these preparations for clinical use. We conclude that subcutaneously injected proinsulin has prolonged pharmacokinetics in plasma and can normalize plasma glucose in NIDDM characterized by severe hyperglycemia; as compared with the hypoglycemic effects of regular insulin, those of proinsulin are mostly due to suppression of hepatic glucose output, with little stimulation of glucose disposal and less hypoglycemia; and proinsulin may have a role in the treatment of NIDDM.

In vivo deactivation of proinsulin action on glucose disposal and hepatic glucose production in normal man.

We have studied the deactivation of the in vivo actions of insulin and biosynthetic human proinsulin (recombinant DNA) to stimulate the glucose disposal rate (GDR) and to inhibit hepatic glucose output (HGO) in man. Twelve healthy, lean, young subjects were studied using a modification of the euglycemic glucose clamp technique. Subjects received 4-h infusions on separate occasions of insulin (15 mU/m2/min equivalent to 0.54 microgram/m2/min) or proinsulin (2.75 micrograms/m2/min), achieving steady-state serum levels of 32 +/- 3 microU/ml (equivalent to 0.23 +/- 0.02 pmol/ml) and 3.7 +/- 0.2 pmol/ml, respectively. Suppression of HGO was similar (83-84%) with proinsulin and insulin, but stimulation of GDR above basal was greater with insulin (3.41 +/- 0.43 versus 1.98 +/- 0.28 mg/kg/min, P less than 0.001). Following cessation of the hormone infusions, serum proinsulin concentration fell in a biphasic fashion with half-times of 25 and 146 min for the two phases. Serum half-disappearance time for insulin was 5 min. Deactivation of the hormone's effects to stimulate GDR was 50% complete by 35 min after insulin and 71 min after proinsulin. In contrast, 50% of the recovery times for the effect on suppression of HGO were 55 min after insulin and 188 min after proinsulin. Serum glucagon levels did not differ significantly after the insulin and proinsulin infusions. In summary: (1) Deactivation of proinsulin and insulin's effects to suppress HGO proceeds more slowly than deactivation of their effects to stimulate GDR; and (2) There is a markedly prolonged and disproportionately delayed deactivation of proinsulin's effects on suppression of HGO. This later finding may prove of therapeutic value in the treatment of diabetes mellitus.

Immunogenicity of recombinant DNA human insulin.

We postulated that human insulin of recombinant DNA origin would be a poor immunogen and might prove to be less immunogenic than purified pork insulin. Results are reported for 100 diabetic subjects not previously treated with insulin. Individuals completed the first 12 months of a clinical trial of human insulin of recombinant DNA origin. These patients are contrasted with 121 similar individuals who are taking part in a trial of purified pork insulin. Prior to therapy, species-specific binding of 125I human insulin and pork insulins and insulin bound to antibody were undetectable in all individuals. In patients treated with human insulin of recombinant DNA origin, binding of 125I human insulin increased to 10 +/- 1.2% at 12 months versus increases in binding of 125I pork insulin in pork insulin-treated patients to 12.6 +/- 1.4% (NS). Mean percentages of species-specific binding tended to reach a plateau in the human insulin-treated group but continued to increase in the pork insulin group (p less than 0.001). Median bound values were nil throughout in patients treated with human insulin, but increased to 52 mU/l in the pork insulin group with significantly less bound insulin seen in the former group at all visits (p less than 0.001). The percentage of individuals who remained antibody free at 12 months, as indicated by bound insulin, was 56% in the human insulin-treated patients and 40% in the patients treated with pork insulin (p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)