Correlationship between Diabetes Mellitus and Chronic Carbon Monoxide Intoxication ()
1. Introduction
Diabetes mellitus (DM) is a group of metabolic disorders characterized by a high blood glucose concentration over a prolonged period of time [1] . Diabetes is due to either the pancreas not producing enough insulin, or the cells of the body not responding properly to the insulin produced [2] . There are three main types of diabetes mellitus: type 1, type 2 and gestational. Symptoms often include frequent urination, increased thirst, and increased appetite [3] . Diabetes mellitus is characterized by recurrent or persistent high blood glucose, and is diagnosed by demonstrating fasting plasma glucose concentration ≥ 7.0 mmol/L (126 mg/dL) and glycated hemoglobin (HbA1C) ≥ 48 mmol/mol (≥6.5 DCCT %) [4] [5] .
The International Diabetes Federation (IDF) Atlas Ninth Edition 2019 provides the latest figures, information and projections on diabetes worldwide. The prevalence worldwide is approximately 463 million adults (20 - 79 years) living with diabetes; by 2045 this will rise to 700 million. Africa has a prevalence burden of more than 19 million people; by 2045 it will be around 47 million. Nigeria has adult total cases of diabetes mellitus of 2,743,800. Furthermore, it revealed that diabetes caused 4.2 million deaths, gulfed at least USD 760 billion dollars in health expenditure in 2019—10% of total spending on adults.
Carbon monoxide (CO) is a poisonous, colourless, tasteless, odourless and non-irritant gas produced by incomplete combustion of organic materials [6] . It has 200 to 300 times more affinity for haemoglobin (Hb) than oxygen (O2), forming carboxyhaemoglobin which is quite stable [6] . This renders haemoglobin incapable of carrying oxygen resulting in tissue hypoxia.
Carbon monoxide poisoning is the inhalation of large quantity of CO that is harmful to the body. Inhalation of CO above the threshold concentration could result in morbidity or mortality based on the health status and age of the victim. The pathophysiology of CO poisoning is mainly anchored on the mechanism of hypoxia and the most impacted organs are the brain and heart [7] . Others less impacted are lungs, pancreas, liver and spleen [7] . Symptoms of CO poisoning may include headache, sweating, dizziness, dim vision, tremor and loss of consciousness [8] .
Diabetes mellitus is a chronic disease that develops over time. The exact causative agent is not definitive. It is believed to be influenced by hereditary, environment, nutrition and lifestyle [9] . The role of environment has been identified as one of the major causes of diabetes mellitus [10] . Toxic gases such as carbon monoxide are found commonly in the environment, especially amongst nations with poor power supply and infrastructures. Nations with poor power supply rely heavily on generating set for power generation. Generating set is one of the major emitters of CO in Sub-Saharan Africa [11] . Inhalation of carbon monoxide above its threshold consistently over time has been shown to distort biochemical and haematological parameters [11] [12] [13] [14] [15]
A study showed that patients with carbon monoxide poisoning (COP) had a higher risk for DM than non-COP patients [16] . Similarly, elevated concentration of exhaled CO was observed in diabetes reflecting heme oxygenase (HO)-1 induction and oxidative stress [17] . The previous studies did not put into cognizance the direct measurement of serum and vitreous glucose and ancillary biochemical parameters upon exposure to consistent CO. Hence, this study is designed to evaluate the concentrations of serum and vitreous biochemical parameters that are essential in the diagnosis and management of diabetes mellitus. Alterations of these parameters could support the alternative hypothesis that CO has a palpable effect of instigating diabetes mellitus. This study is therefore deliberately conducted to interrogate the relationship between CO and diabetes mellitus using an animal model.
2. Materials and Methods
2.1. Study Area
The animal intoxication and sample extraction were performed at the animal house of the Faculty of Agricultural Sciences, Niger Delta University, Bayelsa State, Nigeria. Similarly, the biochemical analysis was carried in the Chemical Pathology Laboratory of the Niger Delta University Teaching Hospital, Okolobiri, Bayelsa State, Nigeria.
2.2. Ethics Statement
The animals used for the study were treated humanely and according to the dictates of the Animal (Scientific Procedures) Act 1986. The ethical approval was granted by the Bayelsa State Ministry of Health, Bayelsa State, Nigeria.
2.3. Animals, Study Design and Treatments
Age-mated New Zealand white male albino rabbits obtained from Plateau State were housed for two weeks in ventilated cages prior for use and were kept under standard conditions with ad libitum access to sterile water and fed a soy-free breeding diet bought in Swali market, Yenagoa, Bayelsa State. Housing conditions were carefully controlled (lights on at 07:00, off at 19:00, temperature 19˚C - 21˚C, humidity 45% - 65%).
Rabbits showing signs or symptoms of illness prior to exposures were excluded from the study. A total of 20 rabbits constituted the sample size as validated using Mead’s resource equation [18] .
After two weeks of acclimatization, the rabbits were randomly allocated into four groups. The first group was designated controls that were exposed to air only (n = 5). The remaining three groups of rabbits were exposed daily whole-body to CO for 30 min for 10, 20, or 30 days (n = 5/group). The source of the CO was a portal Sumac generating set. All CO concentrations were constantly monitored using a Carbon Monoxide Meter Gasman-CO (PCE Instrument, UK). Exposure concentrations were never greater than 200 ppm in the chamber. This level was selected based on earlier studies of Goldstein [19] and Struttmann et al. [20] , wherein 200 ppm was found to reflect CO concentration that will not lead to immediate mortality and morbidity. At 30th minutes after the final exposure, CO-treated rabbits and their aged-matched and weight-matched controls were euthanized mechanically. Bio-samples (i.e., vitreous humor and blood) were then collected for analyses (see below).
2.4. Sample Collection
Vitreous humor samples were collected by the method of Coe [21] , whereas blood samples were collected from the heart using the method of Ness [22] . Both samples were collected into plain containers. The samples were centrifuged and supernatant separated into other plain containers for immediate laboratory analysis.
2.5. Laboratory Analysis
Serum and vitreous glucose were analyzed using glucose oxidase method. Lipid profile, electrolytes, proteins, and renal function markers were measured using methods approved by the World Health Organization (WHO).
2.6. Statistics
Values were expressed as mean ± SEM. Comparison of treatment effects used one-way ANOVA followed by the Bonferroni post hoc test when multiple treatment groups were compared. Pearson correlation was also used to validate relationships between glucose and other essential parameters in the diagnosis of diabetes mellitus. Statistical Package for Social Sciences program v.18-21 (SPSS Inc., Chicago, IL) was employed as the statistical software package.
3. Result
Table 1 indicated a significant increase in vitreous glucose, creatinine and urea observed across the studied groups, while concentrations of vitreous total cholesterol, triglyceride, total protein, globulins, sodium, potassium and pH decreased significantly. Table 2 shows a significant increase in concentrations of serum glucose, triglyceride, creatinine and, on the contrary, serum cholesterol, total proteins, globulins, potassium, and pH activity decreased. Table 3 and Table 4 show a correlational association between glucose and other associated parameters in the vitreous humor and serum respectively. Vitreous glucose/pH showed a strong significant negative correlation (r = −0.505, p = 0.046), whereas vitreous glucose/creatinine and glucose/urea showed a strong significant positive correlation (r = 0.604, p = 0.013; and r = 0.57, p = 0.019). Vitreous glucose/potassium and glucose/globulin showed a weak negative correlation (r = −0.550, p = 0.027; and r = −0.231, p = 0.013) respectively. Serum glucose/potassium, glucose/pH, glucose/cholesterol, glucose/total protein and glucose/globulins showed strong significant negative correlations (r = −0.583, p = 0.018; r = −0.728, p = 0.01; r = −0.706, p = 0.02; r = −0.508, p = 0.044 and r = −0.591, p = 0.016) respectively in Table 4.
Table 1. A multiple comparison of vitreous diabetes mellitus indicators on the basis of duration of chronic CO intoxication.
Legend: TC = Total Cholesterol; TG = Triglyceride; TP = Total Protein; ALB = Albumin; GLO = Globulin; Symbols—a: p < 0.05 vs control, b: p < 0.05 vs Day 10, c: p < 0.05 vs Day 20; Data are expressed as mean ± SD; Significant at 0.05 Confidence (p < 0.05); Concentration of acute CO intoxication = ≤200 pm.
Table 2. A multiple comparison of serum diabetes mellitus indicators on the basis of duration of chronic CO intoxication.
Legend: TC = Total Cholesterol; TG = Triglyceride; TP = Total Protein; ALB = Albumin; GLO = Globulin; Symbols—a: p < 0.05 vs control, b: p < 0.05 vs Day 10, c: p < 0.05 vs Day 20; Data are expressed as mean ± SD; Significant at 0.05 Confidence (p < 0.05); Concentration of acute CO intoxication = ≤200 pm.
Table 3. Relationship between vitreous glucose concentration and ancillary parameters in diabetes mellitus investigations.
*Correlation is significant @ 0.05; **Correlation is significant @ 0.01.
Table 4. Relationship between serum glucose concentration and ancillary parameters in diabetes mellitus investigations.
*Correlation is significant @ 0.05; **Correlation is significant @ 0.01.
4. Discussion
The study discovered a significant alteration in vitreous and serum concentrations of some of the studied biochemical parameters in the experimental groups intoxicated with moderate concentration of CO (Table 1 & Table 2). Also, a handful of correlations either positive or negative were also observed between glucose and some ancillary parameters used in the diagnosis and management of diabetes mellitus (Table 3 & Table 4). These findings form the nutshell of this study as X-rayed below.
This study observed a significant increase in vitreous and serum glucose concentration in the experimental groups intoxicated with moderate concentration of CO (Table 1 & Table 2). Carbon monoxide perpetrates its ferocity through denial of the body of adequate oxygen supply or hypoxia [7] . In addition to hypoxia, carbon monoxide poisoning may induce immunological and inflammatory reactions in all organs in the human body by producing reactive oxygen species, which are longer lasting and independent of hypoxia [23] [24] . These cumulatively could be the basis of the hyperglycaemia observed in this study. The palpable effect of hypoxia in provoking diabetes mellitus or its complications has been shown by couple of researchers [25] [26] . On the contrary, a review article conducted by Veronica et al. [27] suggested that two environmental toxins, arsenic and dioxin (dibenzo-p-dioxins), may have some relationship to an increased risk for diabetes. Carbon monoxide was not included by the researchers as a risk factor of diabetes mellitus.
A serial significant decrease in concentrations of vitreous and serum total protein and globulin in CO intoxicated groups was observed when compared with the controls (Table 1 & Table 2). The decrease in vitreous or serum total protein could have been orchestrated by the fall in vitreous or serum globulin. This is due to the non-significant concentration of albumin across the experimental groups. Globulin is an immune protein used as defense by the body against foreign or toxic agent invasion. A fall in total protein and globulin has been shown to be an attribute of immune suppression or depression [28] . A depressed immune system is an opening of floodgate to a lot of diseases. Hence, the depressed immune system could be one of the scientific bases of the provocation of diabetes mellitus. This is further corroborated by the positive correlations between serum glucose and globulin (Table 4), and serum glucose and serum total protein (Table 4). Decreased cellular response and cellular innate immunity has been implicated in diabetes mellitus [29] which concurred with this study. Furthermore Weaver [23] and Hampson et al. [24] also posited the effect of CO in compromising the immunological status of the body which is in accordance with the posture of this study.
However, this study revealed a significant decrease in concentration of vitreous and serum potassium in the CO intoxicated groups (Table 1 & Table 2). Potassium is the main positively charged electrolyte in the intracellular fluid (ICF), which determines the amount of water inside the cells. Potassium helps the body regulate fluid, send nerve signals and regulate muscle contractions [30] . It is believed that potassium causes the release of insulin from the beta cells of the pancreas [31] . Low concentrations of potassium could be inimical to the efficiency of the pancreas in adequately secreting insulin. A review article emphatically stated that low concentration of potassium can increase the chance of developing diabetes [31] . Hence, the finding on the decrease in potassium concentration further validates the potential risk of diabetes mellitus resulting from CO intoxication. Carbon monoxide could have an inhibitory or alterative effect on potassium concentration which also forms strings of actions cascading to the manifestation of diabetes mellitus.
Vitreous and serum sodium concentration exhibited a significant decrease as the duration of CO intoxication increases (Table 1 & Table 2). Also, a positive correlation was established between serum sodium and serum glucose (Table 4). The result of this study is in consonance with the rule of thumb in clinical medicine; which advanced that serum sodium concentration decreases by 1.6 mEq/l for every 100 mg/dl increase in glucose concentration due to water shifts from the intracellular to the extracellular compartment [32] . An experimental study in healthy subjects found significantly greater decreases in sodium concentration than expected when using the standard correction factor, especially when glucose concentrations were above 400 mg/dl [33] . Serum chloride also exhibited a decrease in concentration. A decrease concentration of serum chloride is a known risk factor of potential diabetes mellitus. Decreased chloride concentration is related to diabetes mellitus, or a family history of diabetes mellitus [34] . A study on anion gap showed a distorted chloride in diabetes [9] .
Vitreous and serum pH value showed a significant decrease in activity (Table 1 & Table 2). The decrease is scaled towards acidity which is a major attribute of ketoacidosis observed commonly in diabetes mellitus. The finding of this study is in agreement with the stance of Yukimura et al. [35] , which established that low pH is significantly associated with abnormal glucose tolerance. Therefore, measuring pH might prove useful for identifying patients at high risk for diabetes. Agoro et al. [9] also posited that glucose impairment has the preponderances of eliciting acidotic condition in the body.
Vitreous and serum total cholesterol concentration decreased significantly upon progressive exposure to moderate CO concentration (Table 1 & Table 2). Similarly, vitreous triglyceride significantly decreased in the vitreous, whereas increased in the serum. Literature has shown that diabetes tends to lower “good” cholesterol concentrations and raise triglyceride and “bad” cholesterol concentrations, which increases the risk for heart disease and stroke. This common condition is called diabetic dyslipidemia [36] . Triglyceride is potentially useful for predicting T2DM in clinical practice. It is a potential mediator of association between BMI and T2DM development [37] . Authors such as Zhang et al. [38] and Lee et al. [39] supported the predictive usefulness of triglyceride. However, Sargsyan and Herman [40] posited that the increase in triglyceride in diabetes mellitus is due to dysregulation of hepatic carbohydrate sensing systems. On the contrary, Beshara et al. [41] showed that sustained increments in serum triglyceride concentration, even within the accepted normal range, are an independent risk factor for diabetes mellitus and impaired fasting glucose in normoglycemic participants.
The significant increase in vitreous and serum creatinine and urea concentrations are an indication of renal dysfunction (Table 1 & Table 2). Furthermore the correlation between vitreous creatinine and urea concentrations and that of glucose concentration is a further proof to the relationship between renal function markers and glucose (Table 3). The source of the increase in concentrations of the renal function markers is questionable as both elevation of glucose or the direct toxicity of CO could initiate the pathophysiology of renal dysfunction. There is a relationship which exists between diabetes mellitus and raised creatinine concentration [42] . Usually, this situation arises when DM has been there for a long time and not controlled and such a situation is referred to as diabetic nephropathy. The reason adduced rule out the possibility of hyperglycaemia causing diabetes mellitus. The finding of this study contradicts the stance of Hjelmesæth et al. [43] which bared that a low serum creatinine concentration is associated with type 2 diabetes, rather than the increase observed in this study. Hence, it could be deduced that the leap in the renal function biomarkers could have emanated from CO intoxication and not the effect of hyperglyceamia.
The major limitation noted in the study is the use of animal model. An advocacy for the use human is apt. Also, more biochemical parameters should be incorporated into the study to increase the scope. Paucity of funds was the major constraint in increasing the scope of the study.
Funding
No funding was gotten from any source or funding organizations. All financial implications were contributions made by the three authors.
Acknowledgements
Special appreciation to the staff of Eni-yimini Laboratory (EL) LTD for the sample collection and biochemical analysis.