(OR19) FREE RADICAL-MEDIATED DESTRUCTIVE PROCESSES IN INSULIN­ DEPENDENT AND INSULIN-INDEPENDENT DIABETES MELLITUS: PROTECTIVE ACTION OF THE ANTIOXIDANT BIO-NORMALIZER

Title  FREE RADICAL-MEDIATED DESTRUCTIVE PROCESSES IN INSULIN­ DEPENDENT AND INSULIN-INDEPENDENT DIABETES MELLITUS: PROTECTIVE ACTION OF THE ANTIOXIDANT BIO-NORMALIZER
Year
Author  Ludmila G. Korkina, Igor B. Afanas’ev,  Elena B. Mikhal’chik, Elena A. Ostrachovich, Michail I. Balabokin, and James A. Osato
Publisher

 

 

FREE RADICAL-MEDIATED DESTRUCTIVE PROCESSES IN INSULIN­ DEPENDENT AND INSULIN-INDEPENDENT DIABETES MELLITUS: PROTECTIVE ACTION OF THE ANTIOXIDANT BIO-NORMALIZER (Pilot clinical trials)

 

 

Ludmila G. Korkina,*)&) Igor B. Afanas’ev,*)  Elena B. Mikhal’chik,*) Elena A. Ostrachovich,*) Michail I. Balabokin,**) and James A. Osato,#)

 

*) Russian Medical University, Moscow 117513, Russia
**) Institute of Diabetes, Moscow, Russia
#) Sun O International, Gifu 500, Japan
&) To whom the correspondence should be directed

 

 

INTRODUCTION

It has already been long known that free radicals play definite role in the development of diabetes mellitus.  Thus,  in  1986  Grankvist  and  Marklund  [1] found  that  the  isolated pancreatic  β-cell membranes   are  the  target  for  the  attack  of  extracellularly  generated oxygen  radicals. The injury was completely suppressed by exogenous SOD and catalase but not hydroxyl radical scavengers. It has been hypothesized that oxygen radicals produced by inflamed cells may cause irreversible damage of β-cell islet in juvenile diabetes. Subsequent studies in patients and diabetic animals have provided substantial evidence for the involvement of oxygen radicals produced by the monocyte/macrophage system and neutrophils in the development of diabetes mellitus [2-6].

Free radical-mediated damage in diabetes mellitus is apparently originated from both the activation of phagocytes and the prooxidant effect of elevated glucose level. Indeed, several studies suggested that elevated glucose level in diabetic patients and experimental animals can cause membrane and lipoprotein lipid peroxidation [7-9]. An increase in lipid peroxidation   and the suppression   of the activities of antioxidant enzymes (erythrocyte SOD, GSH peroxidase, and catalase) have also been demonstrated [10-12]. Another possible mode of free radical damaging activity in diabetes millitus can be the reduction of NO production leading to imbalance in relaxing and contracting factors [13].

All these data as well as a certain success achieved in the treatment of diabetic  animals with antioxidants and chelators [14,15] seem to us to be a reliable reason for carrying out pilot clinical study of the treatment of diabetic patients with nontoxic natural antioxidants and chelators. Earlier, we have shown that Bio-normalizer (BN), a natural Japanese health supplementation prepared by fermentation of Carica papaya, exhibits antioxidant and chelating properties, being an efficient modulator of free radical production by inflamed leukocytes and macrophages [16,17]. Now, we have studied the effects of short-term BN administration to the patients with insulin-dependent and insulin-independent diabetes mellitus (Type I and II) in two randomized double-blind clinical trials. The parameters of organism’s free radical status before and after completing clinical trials such as oxygen radical release by monocytes and granulocytes and the activities of antioxidant enzymes were determined. In addition, the effect of BN on nitric oxide production by blood leukocytes was studied. It was found that BN was able to normalize free radical-mediated processes in diabetic patients that may to certain extent contribute to the improvement of their clinical conditions.

 

 

PATIENTS AND STUDY DESIGN

Randomized double-blind clinical trial I

30  adult  patients  of  both sexes  between  20 and  43 years  with type  I  insulin-dependent diabetes mellitus (IDDM) took part in pilot clinical study after their informed content. Patients were given insulin at appropriate dosage, and IDDM was compensated and well controlled in all cases. Patients were divided into two groups: Group I of 15 patients, who were given insulin and conventional therapy, and Group 2 of 15 patients, who were given insulin, conventional therapy plus 2 sachets (6 g BN) a day for 28 days. Both groups were similar in age, sex, body weight, the duration of IDDM and recent glycemic control. Health adults’ age-matched volunteers were used as a control group.

 

 

Randomized double-blind clinical trial II

24 adult patients of both sexes between 20 and 48 years suffered from insulin-independent diabetes mellitus (IIDM) (type II) took part in pilot clinical study after their informed content.  Patients were randomized into two groups: Group 1 of 9 patients who, were given conventional sugar-decreasing therapy, and Group 2 of 15 patients, who were given conventional therapy plus 2 sachets (6 g BN) a day for 28 days. 9 adult healthy people were used as a control group.

 

 

MATERIALS AND METHODS

Lucigenin, luminol, epinephrine, 12-O-phorbol-13-myristate acetate (PMA), zymosan, N­ monomethyl-L-arginine (L-NAME), Monoprep, Ficoll-Hepaque, CuZnSOD, MnSOD, and catalase were purchased from Sigma Co., St.Louis.

 

Monocyte and granulocyte isolation.

Mixed mononuclear cells and granulocytes from blood samples of fasting subjects were separated by density gradient centrifugation [18]. Blood was collected into Beckton­ Dickinson vacutaneers containing heparin and then layered over a Hipaque or Monoprep gradients   to isolate   granulocytes and monocytes, respectively.  After centrifugation at 500xg for 30 min at 23°C, the bands of leukocytes were removed by aspiration, and the cells were washed twice with the ice-cold HBSS. The numbers of monocytes in mononuclear cell population and of neutrophils in granulocyte population were verified by the Coulter Counter analysis. The cells were finally resuspended in HBSS containing   mM glucose and 5% heat-inactivated calf serum. Cell suspensions were kept on ice until CL analysis.

 

Chemiluminescent analyses.

Lucigenin- and Luminol-amplified chemiluminescence (CL) produced  by monocytes  or neutrophils was measured under continuous mixing on a LKB chemiluminometer (Wallach  Oy, Finland  at 37°C)  as it has been described  earlier  [19].  Cell suspension (105 cells) was added into the polysterene cuvette containing 50 µM Luminol or lucigenin in preheated HBSS (1 mL) and incubated for 5 min. Then, the intensity of spontaneous CL was registered continuously. After that, PMA (10 ng) or opsonized zymosan (1 mg) were added, and the CL response to stimuli was measured as the difference between the maximal intensities of stimulated and spontaneous CL.

NO  production  by  monocytes  was  determined in a similar manner  as  a  difference between  luminol-amplified CL in the absence  and presence  of L-NAME, the inhibitor  of NO-synthase.

 

 

CuZnSOD and MnSOD activities

The SOD activity in erythrocytes and neutrophils was determined by measuring lucigenin-amplified CL produced during the autoxidation of epinephrine in alkaline medium (the modified Misra and Fridovich method [20]). To prepare the SOD-containing material, washed erythrocytes or leukocytes were lysed by hypotonic shock, and hemolysate or leukocyte lysate were added to the mixture of cold water (3.5 mL), ethanol (1.0 mL), and chloroform (0.6 mL). The mixture was vigorously shaken for 3-5 min and centrifuged at 3000xg   for 10 min. The clear top layer possessing SOD activity was immediately frozen at -20°C until performing the further analysis.  Aliquot of SOD­ containing extract (50 µL) was added to 0.05 M carbonate buffer (pH 9.6) containing EDTA (100 µM) and lucigenin (100 µM). The reaction was started by the addition of 50 µL epinephrine (a final concentration of 50 µM), and the CL intensity was measured continuously). The SOD activity was determined by the use of the calibration curve. MnSOD activity in leukocytes was measured in the presence of 5 mM NaCN, and CuZnSOD activity was calculated as a difference between   total SOD and MNSOD activities.  Protein content was determined by the Lowry method.

 

Statistical analysis

Dinamics of clinical and laboratory parameters before and after BN administration in both experimental and control groups was analyzed by the use of non-parametric Wilcockson criteria. Clinical and laboratory data were expressed as mean±SD. Data were analyzed statistically using nonpaired Student’s test. Statistically significant difference assumed at the 5% level.

 

 

RESULTS

It was found  that the production  of oxygen  radicals  by circulating leukocytes  (monocytes and neutrophils) from patients with well-controlled IDDM (the first clinical trial) was significantly decreased  as  it  is seen  from  the  measurement of  luminol-  and  lucigenin- amplified CL produced  by nonstimulated, PMA- stimulated, and zymosan-monocites and neutrophils (Tables 1-4). BN-treatment of patients sharply increased practically all types of CL produced by either monocytes or neutrophils frequently make it very close to the values for normal donors. In contrast, two tendencies were observed for patients suffered from  insulin-independent diabetes mellitus (Clinical trial 2): for 9 patients (Subgroup A) monocytic  oxygen radical  production  was equal or even higher than that in control group, while 6 patients (Subgroup B) are characterized by reduced oxygen radical  production. BN treatment of the patients of both subgroups normalized the radical production in subgroups, decreasing enhanced values and increasing reduced values (Table 1).

Nitric   oxide   production   was   measured   as the difference   between   the values   of monocytic luminol-amplified CL in the absence and presence of L-NAME, an inhibitor of NO-synthase (Table 5).  It is seen that BN treatment significantly enhanced NO production by monocytes of patients with IDDM.

CuZnSOD, MnSOD, and catalase activities in IDDM and IIDM circulating blood cells did not differ from those in donor cells, and BN treatment did not affect the initial levels of the activities of antioxidant enzymes (data not shown).

 

 

DISCUSSION

Our findings suggest that oxidative metabolism of leukocytes (monocytes and neutrophils) indeed significantly affected in the patients with diabetes mellitus. To our surprise, we found drastic difference in the oxidative metabolism of leukocytes from patients with insulin-dependent and insulin-independent diabetes mellitus: the oxygen radical production by IDDM cells was sharply suppressed in comparison with normal donors, while patients with IIDM must be divided into two subgroups with enhanced and reduced monocytic production of oxygen radicals. Our data for  IDDM  patients  do  not contradict the  results  obtained  earlier  for the patients with pronounced but not newly diagnosed IDDM [3, 21] because the initial   stage of diabetes mellitus is apparently always characterized by the enhanced level of oxygen radical production by leukocytes. However, insulin is an inhibitor of oxygen radical release by leukocytes [21], therefore its prolonged administration to patients may be a major reason of the reduced oxygen radical release by leukocytes.

In accord with the above proposal, leukocytes from IIDM patients should produce the enhanced level of oxygen radicals. It seems to be the case for 9 of 15 patients with insulin­ independent diabetes mellitus although oxygen radical production by monocytes of 6 other patients was not enhanced or even slightly decreased (Table 1). The reason of that remains unclear.

The impaired oxygen metabolism of circulating phagocytes can be an origin of the enhanced susceptibility of diabetic patients to infections and may at least partly explain numerous immune abnormalities also frequently observed in these patients. Therefore, we believe that the application of Bio-normalizer capable of normalizing the oxygen radical production by inflammatory cells [16, 17] is a perspective route for combating these toxic manifestations. It was found that BN administration indeed brings the enhanced and reduced levels of oxygen radical production by both IDDM and IIDM cells to normal values. (It should be stressed that there were no any significant changes in the leukocyte oxidative metabolism of patients of control groups). It seems to be very important that monocytic NO production was also normalized after BN administration that can induce improvement in vascular permeability and tonus and lead to fast wound healing.

 

 

REFERENCES

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  2. Wierusz-Wysocka B.,Wysocki H., Siekierka H., Wykretowicz A., Szczepanik F., Klimas K., Evidence of polymorphonuclear neutrophils (PMN) activation in patients with  insulin­ dependent diabetes mellitus. J. Leukocyte Biol.  1987,42:519-523.
  3. Hiramatsu K. and Arimori S., Increased superoxide production by mononuclear cells of patients with hypertriglyceridemia and diabetes. Diabetes 1988, 37: 832-838.
  4. Brenner H.H., Burkart V., Rothe H., and Kolb H., Oxygen radical production  is increased in macrophages from diabetes prone BB rats. Autoimmunity 1993, 15: 93-98.
  5. Horio F., Fukuda M., Katoh H., Petruzelli M., Yano N., Rittershaus C., Bonner-Weir S., and Hattori M., Reactive oxygen intermediates in autoimmune islet cell destruction of the NOD mouse induced by peritoneal exudate cells (rich in macrophages) but not T cells. Diabetologia 1994, 37: 22-31.
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  8. Jain S.K., McVie R., Duett J., and Herbst J.J., Erythrocyte meinbrane lipid peroxidation and glycosylated hemoglobin in diabetes. Diabetes 1989, 38: 1539-1543.
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  13. Giugliano  D.,  Ceriello  A, and  Paolisso  G.,  Diabetes  mellitus,  hypertension,  and cardiovascular disease: which role for oxidative stress? Metabolism 1995, 44: 363-368.
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  16. Osato J.A., Afanas’ev  IB., Cheremisina Z.P.,  Suslova T.B., Abramova N.E., Mikhalchik   E.V.,  Deeva  IB., Santiago L.A., and  Korkina L.G.,  Bio-normalizer  as  a modulator of phagocytosis and free radical production by murine inflamed  neutrophils and macrophages. Phys.Chem.Biol.Med. 1995, 2: 87-95.
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Table 1
Luminol-amplified CL produced by blood monocytes of control and BN-treated patients(m ± SD)

Group Spont. CL
Before
Spont. CL
after
PMA- stim. CL before PMA- stim. CL after Zymosan- stim. CL before Zymosan- stim. CL after
Control (trial  1)

56±40

74±60

220±100

320±190

300±200

560±310

BN-treated
(trial  1)

100±80

240±100

460±220

840±340

520±400

3350±160

Control, (trial 2)

1200±450

650±500

8050±650

15500±6200

BN-treated (trial 2). subgroup I

1020±220

615±360

21100±8400

7100±1970

BN-treated (trial 2),

100±60

530±250

1720±640

3800±960

Normal donors

520±210

4220±250

 

 

Table 2
Lucigenin-amplified CL produced by blood monocytes of control and BN-treated patients(m±SD)

Group Spont. CL
before
Spont. CL
after
PMA- stim. CL before PMA- stim. CL after Zymosan- stim. CL before Zymosan- stim. CL after
Control,
(trial 1)
13±10 14±10 45±25 43±19 30±20 5l±30
BN-treated
(trial 1)
6±3 12±7 40±30 120±80 90±80 810±450

 

 

Table 3
Luminol-amplifted CL produced by blood neutrophils of control and BN-treated patients(m ± SD)

Group Spont. CL
before
Spont. CL
after
PMA- stim. CL before PMA- stim. CL after Zymosan- stim. CL before Zymosan- stim. CL after
Control,
(trial 1)

190±130

190±130

990±470

770±500

3370±2380

1650±1500

BN-treated
(trial 1)

210±180

920±470

1270±1050

2320±1700

3140±2500

15500±7700

 

 

Table 4
Lucigenin-amplified CL produced by blood neutrophils of control and BN-treated patients(m ± SD)

Group Spont. CL
before
Spont. CL
after
PMA- stim. CL before PMA- stim. CL after Zymosan- stim. CL before Zymosan- stim. CL after
Control,
(trial 1)

35±17

23±11

98±59

103±80

210±160

135±110

BN-treated
(trial 1)

27±18

49±25

75±50

260±150

390±300

2100±700

 

Table 5
L-NAME –inhibited luminol-amplified CL produce by monocytes of control and BN-treated patients(m ± SD)

Group

PMA-(PMA+L-NAME)

Zymosan- (Zymosan+L-NAME)

before

after Before

after

Control, (trial  1)

160

130

110

180

BN-treated(trial 1)

290

480

160

1480