BACKGROUND AND OBJECTIVES. Several reports have shown that coexistence of diabetes mellitus and COVID-19 is one of the risk factors for poor outcome and increased mortality. Rapid metabolic deterioration with development of diabetic ketoacidosis (DKA) or hyperglycemic hyperosmolar syndrome (HHS) may result due to the acute insulin secretory capacity loss, stress condition and the cytokine storm. In this review, we aim to describe the prevalence of hyperglycemic crises(DKA/HHS) in patients with COVID-19 infection as well as their clinical outcomes. METHODS. An intensive search was done using the WebMD, PubMed, Medline and Google Scholar databases for articles published between December 2019 to October 2020 that identified the number of patients who developed DKA and/or HHS among those who were admitted for COVID-19. Their clinical outcomes were likewise described. RESULTS. This review included 4 articles in which individual quality was assessed. A total of 1282 patients were admitted for COVID-19 and the prevalence of DKA was 1.32%. HHS was not reported in any of the studies. Five (29.4%) of the patients with DKA and COVID-19 died and 12 (70.6%) recovered. CONCLUSIONS. A significant number of COVID-19 patients developed DKA and it is associated with a high mortality rate. This reimposes the need for an appropriate algorithm for the optimal management of concomitant COVID 19 and hyperglycemic crises to avoid morbidity and mortality. Additionally, there is paucity of large-scale studies describing the prevalence of DKA/HHS in patients with COVID-19.
Diabetic Ketoacidosis ; COVID-19 ; Water-Electrolyte Imbalance ; Acid-Base Imbalance ; Coma

ABSTRACT This study aimed to determine the fluoride and pH levels of beverages likely to be consumed by children in Malaysia and to estimate daily fluoride intake from consumption of these beverages. A convenience sampling of 120 ready-to-drink beverages were purchased and categorised into 11 groups (UHT recombined milk, fresh milk [pasteurised], cultured milk [probiotic], yogurt beverages, fresh fruit juices, fruit flavoured beverages, soy-based beverages, malt-based beverages, tea, carbonated beverages and bottled waters). Fluoride concentration was measured using a fluoride ion-selective electrode while the pH level was measured using a pH meter. The fluoride concentration in the beverages ranged from 0.02±0.00 mg/L to 2.77±0.06 mg/L. Tea was found to have the highest fluoride concentration. The intake of fluoride from consumption of other types of beverages is below the lowest-observed-adverse-effect level (except tea). The pH of the beverages included in the study ranged from 2.20±0.01 to 7.76±0.00. Carbonated beverages (mean pH: 2.98±0.50) were found to be extremely acidic followed by fresh fruit juices (mean pH: 3.38±0.34) and fruit flavoured beverages (mean pH: 3.90±0.92). The correlation between fluoride and pH levels was weak, τ = 0.058 and not statistically significant (p < 0.35). The majority of the beverages had a low fluoride level and their consumption is unlikely to cause fluorosis except for tea. Almost half of the beverages had a low pH level with carbonated beverages being the most acidic.
Fluoridation ; Carbonated Beverages ; Dental Care for Children ; Acid-Base Imbalance

BACKGROUND: Cisatracurium is a nondepolarizing muscle relaxant. It less likely release histamine and has better cardiovascular stability. It presumably undergoes pH and temperature- dependent, nonenzymatic chemical process, Hofmann reaction. In vitro studies, Hofmann reaction was enhanced with increasing pH, but, in vivo the influence of acid-base imbalance is not well defined. METHODS: To evaluate the effects of acid-base imbalance on the neuromuscular blockade of cisatracurium in the cat, we induced acid-base imbalance and performed cumulative dose-response studies. RESULTS: ED50 of the cisatracurium was significantly reduced in all groups. Dose-response curves from all acid-base imbalance groups did not have significant differences in slopes. But, all showed shift-to-left when compared with control curve, showing decreased ED50. Duration of action was not affected. Recovery index was significantly changed in respiratory and metabolic alkalosis. CONCLUSIONS: It may be concluded that acid-base imbalance significantly augmented the potency of cisatracurium, but, changes of recovery index in this study may be resulted from systemic instability such as unstable hemodynamic state by the prolonged experiment.
Acid-Base Imbalance* ; Alkalosis ; Animals ; Cats* ; Chemical Processes ; Hemodynamics ; Histamine ; Hydrogen-Ion Concentration ; Neuromuscular Blockade*

Conventional hemodialysis, which is based on the diffusive transport of solutes, is the most widely used renal replacement therapy. It effectively removes small solutes such as urea and corrects fluid, electrolyte and acid-base imbalance. However, solute diffusion coefficients decreased rapidly as molecular size increased. Because of this, middle and large molecules are not removed effectively and clinical problem such as dialysis amyloidosis might occur. Online hemodiafiltration which is combined by diffusive and convective therapies can overcome such problems by removing effectively middle and large solutes. Online hemodiafiltration is safe, very effective, economically affordable, improving session tolerance and may improve the mortality superior to high flux hemodialysis. However, there might be some potential limitations for setting up online hemodiafiltaration. In this article, we review the uremic toxins associated with dialysis, definition of hemodiafiltration, indication and prescription of hemodiafiltration and the limitations of setting up hemodiafiltration.
Acid-Base Imbalance ; Amyloidosis ; Dialysis ; Diffusion ; Hemodiafiltration* ; Mortality ; Prescriptions ; Renal Dialysis ; Renal Replacement Therapy ; Urea ; Water

OBJECTIVES: To explore the effects of hypoxic and hypobaric conditions on blood gas and erythrocyte-related indicators in rats. METHODS: SD male rats were exposed to low-pressure hypoxic conditions simulating an altitude of 6500 m in a small or a large experimental cabin. Abdominal aortic blood samples were collected and blood gas indicators, red blood cells (RBCs) count, and hemoglobin (Hb) content were measured. The effects of exposure to different hypoxia times, different hypoxia modes, normal oxygen recovery after hypoxia, and re-hypoxia after hypoxia preconditioning on blood gas indicators, RBCs count and Hb content were investigated. RESULTS: The effect of blood gas indicators was correlated with the length of exposure time of hypoxia and the reoxygenation after leaving the cabin. Hypoxia caused acid-base imbalance and its severity was associated with the duration of hypoxia; hypoxia also led to an increase in RBCs count and Hb content, and the increase was also related to the time exposed to hypoxia. The effects of reoxygenation on acid-base imbalance in rats caged in a small animal cabin were more severe that those in a large experimental cabin. Acetazolamide alleviated the effects of reoxygenation after leaving the cabin. Different hypoxia modes and administration of acetazolamide had little effect on RBCs count and Hb content. Normal oxygen recovery can alleviate the reoxygenation and acid-base imbalance of hypoxic rats after leaving the cabin and improve the increase in red blood cell and hemoglobin content caused by hypoxia. The improvement of hypoxia preconditioning on post hypoxia reoxygenation is not significant, but it can alleviate the acid-base imbalance caused by hypoxia in rats and to some extent improve the increase in red blood cell and hemoglobin content caused by hypoxia. CONCLUSIONS Due to excessive ventilation and elevated RBCs count and Hb content after hypoxia reoxygenation, oxygen partial pressure and other oxygenation indicators in hypoxic rats are prone to become abnormal, while blood gas acid-base balance indicators are relatively stable, which are more suitable for evaluating the degree of hypoxia injury and related pharmacological effects in rats.
Rats ; Animals ; Male ; Acetazolamide ; Hypoxia ; Oxygen ; Erythrocytes ; Hemoglobins ; Acid-Base Imbalance

BACKGROUND: Intraoperative acid-base imbalance frequently occurs during liver transplantation (LT). The purpose of this study was to compare the acid-base changes between cadaveric whole LT and a LT from a living relative using a strong ion approach. METHODS: Twenty-four patients undergoing LT were allocated to a group receiving a LT from a brain dead donor (BD group, n = 12) or a LT from a living, related donor (LD group, n = 12) according to the surgical technique required. Acid-base parameters such as PaCO2, pH, base excess, and serum concentrations of bicarbonate, albumin, lactate, phosphate, and other electrolytes were measured at 30 min after skin incision (T1), 30 min after reperfusion (T2), and 1 h after the arrival at the intensive care unit (T3). The apparent strong ion difference (SIDa), the effective strong ion difference (SIDe), and the strong ion gap (SIG) were calculated using the Stewart equation. RESULTS: There were no significant differences in pH, PaCO2, base excess, SIDa, and SIG between the two groups throughout the entire period of investigation. pH was decreased from T1 to T2, and increased significantly from T2 to T3 in both groups. The serum concentration of lactate was significantly increased from T1 to T2 and T3 in both groups without any intergroup differences. The strong ion gap was significantly increased from T1 to T2 only in the BD group. CONCLUSIONS: During LT from both cadaveric and living related donors, there is a biphasic acid-base change that is characterized by an initial metabolic acidosis and then a metabolic alkalosis, with no significant intergroup differences in acid-base variables.
Acid-Base Equilibrium ; Acid-Base Imbalance ; Acidosis ; Alkalosis ; Brain Death ; Cadaver ; Electrolytes ; Humans ; Hydrogen-Ion Concentration ; Intensive Care Units ; Lactic Acid ; Liver ; Liver Transplantation ; Reperfusion ; Skin ; Tissue Donors

A 54 year old man who had taken puffer fish and noticed generalized weakness 1 hour and 30 minutes afterward was admitted to our I.C.U. due to respiratory arrest and cardiac arrhythmia. He was treated with artificial respiration via pressure cycled respirator, supportive therapy including frequent endotracheal suctioning. fluid administration, correction of acid base imbalance, change of position and antibiotics for prevention of secondary infection. 31 hours afterward, he resumed normal respiration and clear mentality. After 5 days of total admission days, he was discharged without any sequelae.
Acid-Base Imbalance ; Anti-Bacterial Agents ; Arrhythmias, Cardiac ; Coinfection ; Poisoning* ; Respiration ; Respiration, Artificial ; Respiratory Paralysis* ; Suction ; Tetraodontiformes ; Tetrodotoxin* ; Ventilators, Mechanical

Assessment of the adequacy and effectiveness of oxygen therapy is a matter of clinical evaluation and blood gas measurement as long as the administration of oxygen is consistent and predictable. Normal variances in the distribution of ventilation and pulmonary blood flow make the measurement of alveolar oxygen concentrations impratical and complex. To certify the relationship between the fractional inspired oxygen concentration (F1O2) and arterial oxygen tension(PaO2), we performed the blood gas analysis of the anesthetized surgical patients whose inspired oxygen concentrations were 20 to 100% (compressed medical-O2). This paper reports our findings and a discussion of their possible significance. Results were as follows ; 1) There were no differences in systolic, diastolic and mean arterial pressure in the range of 0.2 to 1.0 of F1O2. 2) There was no clinically significant difference in heart rate from 0.2 to 1.0 of F. 3) In the arterial blood gas analysis, PaCO2 and pHa revealed normal value from F1O2 0.2 to 1.0 but PaO2 progressively increased significantly. Patients didn,t reveal arterial hypoxemia and acid-base imbalance from 0.2 to 1.0 of F1O2.
Acid-Base Imbalance ; Anoxia ; Arterial Pressure ; Blood Gas Analysis ; Gases* ; Heart Rate ; Humans ; Oxygen ; Reference Values ; Ventilation

BACKGROUND: Acid-base imbalances are common in critically ill patients; however, the incidence of acid-base imbalances in the medical intensive care units has not been fully determined. In this study, we investigated the incidence and the type of acid-base imbalances in critically ill patients and we assessed which variables were associated with the patients' outcome. METHODS: One hundred eighty-seven patients (122 men, age: 61.2+/-12.8 years) were enrolled. All the patients were admitted to the medical intensive care unit between January 2005 and December 2005. All the data sets included simultaneous measurements of an arterial blood gas with base excess, the serum electrolytes, the anion gap and the APACHE II scores. RESULTS: The mortality rate was 56.7%. The incidence of acid-base imbalances was as follows: 25.1% were single disorders that existed with only a single primary acid-base imbalance, 48.7% were double disorders, 13.4% were triple disorders and 12.8% were normal (no disorders). The incidence of metabolic acidosis was 57.8% and the mortality rate was not different according to the type of acid-base imbalances. There were significant differences between the nonsurvivors and survivors according to the pH (7.34 vs. 7.41, respectively), HCO(-)3 (20.68 mmol/L vs. 25.90 mmol/L, respectively), ECF base excess (-5.19 vs. 1.19, respectively), the anion gap (18.57 mmol/L vs. 13.77 mmol/L, respectively), the corrected anion gap (23.63 mmol/L vs. 17.96 mmol/L, respectively), the serum albumin (2.37 g/dL vs. 2.74 g/dL, respectively), and the APACHE II scores (20.7 vs 17.2, respectively). However, on the Cox proportional hazard regression analysis, only the APAHCE II scores affected the patients' outcome. CONCLUSIONS: There were diverse acid-base imbalances in the critically ill patients and the incidence of metabolic acidosis was highest among the acid-base imbalances. The best predictor of the patients' outcome was the APACHE II scores.
Acid-Base Equilibrium ; Acid-Base Imbalance ; Acidosis ; APACHE ; Critical Illness* ; Dataset ; Electrolytes ; Humans ; Hydrogen-Ion Concentration ; Incidence ; Intensive Care Units* ; Critical Care ; Male ; Mortality ; Serum Albumin ; Survivors

PURPOSE: D-lactate, optical isomer of L-lactate is not a human metabolite. Once the D-lactate enters the human body, it is mainly metabolized in liver. The metabolism of D-lactate can be changed in patients with decompensated liver cirrhosis with the exposure of antibiotics and the frequent trial of lactulose, if neccessory. The aim of this study is to analyze blood D-lactate level in cirrhotic patients and it's relationship with the degree of hepatic insufficiency and acid-base imbalance. METHODS: Plasma L-lactate and D-lactate levels were measured in 40 cirrhotic patients classified by Child-Pugh system with L-LDH and D-LDH with comparison of their changes before and after the use of antibiotics and lactulose(n=14). Also, acid-base disorders were analyzed in 35 cirrhotic patients, and plasma L, D-lactate levels were determined in each acid-base disorder. RESULTS: Plasma D-lactate level was not significantly elevated in cirrhotic patients compared to the control group(2.34+/-.48 mmol/L vs. 1.63+/-.26 mmol/ L, p=NS), but some patients(n=4, 10%) revealed abnormally elevated D-lactate level. The plasma L, D- lactate levels were not different in subgroups classified by Child-Pugh system as well as by underlying causes of liver cirrhosis, and plasma D-lactate level was not sugnificnatly different before and after the exposure of antibiotics and lactulose. Plasma D-lactate level was significantly increased in 3 patients with respiratory alkalosis and metabolic acidosis(12+/-.98 mmol/L) compared to others(p<0.05). CONCLUSION: These results suggest that, regardless of its decompensated degree and exposure to drugs, a subset of patients with liver cirrhosis can develop elevation of D-lactate in blood, particularly when metabolic acidosis is accompanied.
Acid-Base Imbalance* ; Acidosis ; Alkalosis, Respiratory ; Anti-Bacterial Agents ; Hepatic Insufficiency ; Human Body ; Humans ; Lactic Acid ; Lactulose ; Liver ; Liver Cirrhosis ; Metabolism ; Plasma*