- Published: July 31, 2022
- Updated: July 31, 2022
- University / College: London School of Hygiene & Tropical Medicine
- Language: English
- Downloads: 40
Introduction
Cushing’s disease (CD) is the most prevalent etiology of Cushing’s syndrome (CS), presenting with endogenous hypercortisolism caused by an ACTH-secreting pituitary tumor ( 1 ). It is characterized by a series of metabolic disorders, including visceral obesity, hypertension, impaired glucose metabolism, and dyslipidemia, leading to increased cardiovascular risk and a higher mortality rate compared with the healthy population ( 2 , 3 ).
Dyslipidemia secondary to chronic glucocorticoid excess has been reported in 12%–72% of CS patients and was a critical contributor to the increased cardiovascular complications, such as vascular atherosclerosis, coronary artery disease, and heart failure ( 1 ). The lipid abnormalities associated with CS usually present as elevated total cholesterol (TC), low-density lipoprotein cholesterol (LDL-c) and triglyceride (TG) levels, and lower high-density lipoprotein cholesterol (HDL-c) level in patients compared with healthy controls and may persist despite the surgical remission of CS ( 1 , 4 , 5 ). However, the alterations of the lipid profile after surgical correction of hypercortisolism is quite variable in previous studies ( 1 , 4 ).
Furthermore, the pathogenic mechanisms of lipid abnormalities in CS, particularly in CD, are complex and remained largely unknown. Previous studies have shown that glucocorticoids (GC) excess could stimulate both lipolysis and lipogenesis, resulting in increased intravascular triglyceride hydrolysis, hepatic free fatty acid (FFA) production, and very-low-density lipoprotein cholesterol (VLDL-c) synthesis whereas suppression of FFA oxidation ( 5 – 7 ). Hyperglycemia and insulin resistance, as common features in CD, were suggested to play critical roles in determining lipid dysregulation in non-CD populations (e. g., type 2 diabetes mellitus) ( 5 , 8 ). However, few studies are available regarding the relationships between lipid abnormalities and other preoperative metabolic comorbidities in CD patients ( 9 ).
Therefore, this study aimed to evaluate the potential associations between metabolic and hormonal parameters and hyperlipidemia associated with CD at the time of diagnosis. Besides, we investigated the short-term impact of surgical remission on lipid metabolism and assessed the potential parameters that predict the persistence of hyperlipidemia after remission of CD at follow-up.
Methods
Patients
This retrospective study included 104 patients diagnosed with Cushing’s disease (CD) and hospitalized at Peking Union Medical College Hospital, Chinese Academy of Medical Science, from April 2013 to September 2019. Patients were included in the study if newly diagnosis of CD was made based on: typical Cushingoid appearance, e. g., moon face, acne, supraclavicular, and dorsal fat pads; elevated morning serum or 24-h urinary free cortisol (24hUFC) level, absence of circadian cortisol rhythm, increased plasma ACTH level; lack of suppression of low-dose dexamethasone suppression test (LDDST) whereas suppressibility with high dexamethasone suppression test (HDDST); detection of a pituitary lesion on MRI. All patients underwent endoscopic endonasal transsphenoidal surgery for pituitary adenoma resection. The adenoma was carefully separated and completely resected for each patient, and then followed by nasoseptal flap reconstruction of the diaphragm and sellar. The diagnosis was confirmed by postoperative pathology and immunohistological staining results, indicating a pituitary adenoma with ACTH (+).
Patients were excluded if: 1) recurrent CD with previous surgery or radiotherapy; 2) complete medical data at baseline was not available; 3) administration of drugs influencing cortisol metabolism or usage of hypolipidemic medication at the time of diagnosis. Data on clinical and biochemical parameters at diagnosis of CD and at the last follow-up visit were retrospectively extracted from the medical records. A total of 104 patients was included in the investigation of baseline characteristics ( Figure 1 ). Of these, 95 patients were followed up for at least 6 months after surgery, while nine patients were lost to follow-up. Re-evaluation of lipid profile at last follow-up was available in 78 patients, of whom 65 achieved remission and 6 had no remission that constituted the cohort for comparison analysis between baseline and post-surgery parameters.
FIGURE 1
Follow-up flow chart of CD patients included in the study.
Disease duration was calculated as the period from symptom onset to biochemical remission of hypercortisolism. Immediate surgical remission was defined as a serum cortisol level <5 µgdl measured within the postoperative 7 days ( 10 , 11 ). Low-dose glucocorticoid was routinely given to patients with immediate surgical remission and gradually ceased within 3 months to help reducing adverse effects of temporary hypopituitarism. Long-term hydrocortisone replacement therapy (HRT) was required for patients with postoperative hypopituitarism or adrenal insufficiency. Female patients with postoperative hypogonadotropic hypogonadism (HH) were given low-dose estradiol additionally. At follow-up, remission was considered when patients had normalized serum cortisol and 24hUFC levels along with the resolution of clinical symptoms. Recurrence was defined as elevated serum cortisol or 24hUFC above the upper limit of normal range companied by clinical symptoms in patients with initially established remission.
Informed consent was obtained from each patient. This study was approved by the Institutional Review Board of Peking Union Medical College Hospital, Chinese Academy of Medical Sciences and was performed following the ethical standards laid down in the 1964 Declaration of Helsinki and its later amendments.
Clinical and Biochemical Evaluation
Body mass index (BMI) was calculated using the formula weight (kg)/height 2 (m 2 ). Obesity was defined using BMI criteria for Asians as BMI≥28 kg/m 2 . Waist circumference above 88 cm in women and 102 cm in men was defined as visceral obesity. Blood pressure was measured in all patients twice a day, and the average of two measurements was calculated. Hypertension was defined as systolic blood pressure (SBP) ≥140 mmHg or diastolic blood pressure (DBP)≥90 mmHg, or current use of antihypertensive medication. Impaired glucose metabolism (IGM) was defined when impaired glucose tolerance(IGT) (2h glucose after OGTT between 7. 8 and 11. 0 mmol/L) or diabetes mellitus (DM) (fasting blood glucose ≥7. 0 mmol/L or 2h glucose after OGTT ≥11. 1 mmol/L) was diagnosed according to ADA 2014 guidelines, or when patients were on current antidiabetic medication. Hypercholesterolemia was diagnosed when total cholesterol (TC) ≥6. 22 mmol/L, whereas hypertriglyceridemia was diagnosed when triglyceride (TG) ≥2. 26 mmol/L according to the NCEP-ATPIII criteria. The presence of either hypercholesterolemia or hypertriglyceridemia was summarized as hyperlipidemia. All biochemical parameters were evaluated by standard procedures in the routine certified laboratory of our institution. TC, TG, HDL-cholesterol, LDL-cholesterol were determined using Beckman AU5400 automatic biochemistry analyzer and homogeneous methods. Serum cortisol, serum ACTH, 24hUFC, and other hormones were measured with the chemiluminescence method using the commercial kits (DPC Biotechnology and Medical Products Cooperation, Tianjin, China). Glycated hemoglobin (HbA1c) was measured with high performance liquid chromatography. According to the WHO diagnostic guidelines, osteoporosis was defined as low bone density as measured using dual-energy X-ray absorptiometry (DEXA). Hepatic steatosis and atherosclerosis were examined using high-resolution B-mode ultrasonography. Cardiovascular disease (CVD) history was defined as a medical history of myocardial infarction, unstable angina, ischemic stroke, cardiac structural changes, or severe arrhythmia. Patients reported a family history of hypertension or DM in first-degree relatives was considered to have hypertension or DM family history. Patients with long-term HRT were asked to be off their hormonal medication for 48h before blood collection at follow-up.
Statistical Analysis
The normality of data distribution was determined using the Shapiro-Wilks test. Quantitative variables were presented as mean ± standard deviations(SD) or median with interquartile range(IQRs) according to their distribution, and categorical variables were reported as frequency. Differences among independent groups were analyzed using Student’s t-tests for quantitative data with normal distribution, or Mann-Whitney U tests for data with non-normal distribution. Pearson’s Chi-square test was used to compare the differences for categorical variables. Paired t-test or Wilcoxon signed-rank test was used to compare the differences between pre- and post-operation parameters for quantitative variables, whereas the McNemar test was used for categorical variables. Spearman’s correlation coefficients and Partial correlation coefficients were used for correlation analyses. Multivariate logistic regression analysis was used to investigate associations of baseline parameters with the presence of hyperlipidemia before surgery. Data analysis was performed with Statistical Package for Social Sciences (SPSS) Version 25. 0 program (IBM Corporation, Armonk, NY, USA). All statistical tests were two-sided, and p < 0. 05 was considered statistically significant.
Results
Upon diagnosis, hyperlipidemia, hypertension, and impaired glucose metabolism (IGM) were present in 36. 4%, 73. 1%, and 70. 2% of patients with CD, respectively. One hundred and four patients with CD were categorized into two groups: non-hyperlipidemia (NLP) group (n= 68, 65. 4%) and hyperlipidemia (HLP) group (n= 36, 34. 6%). The baseline characteristics of the two groups are shown in Table 1 . Patients with HLP showed higher systolic blood pressure (SBP), 2h-blood glucose during OGTT (2h-BG), morning serum cortisol levels compared with NLP patients (p <0. 05). Also, the prevalence of IGM (88. 9% vs. 60. 3%, p= 0. 002) and diabetes mellitus (DM) family history (19. 4% vs. 4. 4%, p= 0. 03) tended to be higher in patients with HLP than that in NLP patients. There were no significant differences in age, body mass index (BMI), disease duration, diastolic blood pressure (DBP), high-density lipoprotein cholesterol (HDL-c), tumor size, plasma ACTH between the two groups. Other pre-operative comorbidities, including visceral obesity, osteoporosis, hepatic steatosis, and atherosclerosis, were also comparable between groups regardless of the HLP status. An association was detected between baseline triglycerides (TG) and SBP (r= 0. 297, p= 0. 003), and fasting blood glucose (FBG) (r= 0. 338, p= 0. 001), and HbA1c (r= 0. 299, p= 0. 004), respectively, after adjustment for all covariates including age, BMI, serum cortisol level, plasma ACTH level, and disease duration. Furthermore, the logistic regression analysis showed that IGM (OR= 4. 682, 95%CI: 1. 378–15. 909) and morning serum cortisol level (per 10 μg/dl change) (OR= 1. 807, 95%CI: 1. 107–2. 949) are independent risk factors of the preoperative presence of hyperlipidemia as a comorbidity in patients with CD regardless of age, obesity and disease duration ( Table 2 ).
TABLE 1
Baseline characteristics at diagnosis in CD patients with or without hyperlipidemia.
TABLE 2
Logistic regression analyses of hyperlipidemia at diagnosis with predicting baseline parameters.
After surgery, immediate remission in postoperative 7 days was achieved in 85. 6% (89/104) patients. No significant difference in prevalence of surgical complications (16. 2% vs. 19. 4%, p= 0. 892) and immediate postoperative remission (85. 2% vs. 86. 1%, p= 1. 000) was found between NLP and HLP groups. At the last visit, a total of 78 patients had available biochemical data, of which 65 achieved remission after surgery. Improvement in lipid profile with a significant reduction in total cholesterol (TC) and low-density lipoprotein cholesterol (LDL-c) level was observed in these 65 patients at follow-up when compared with baseline levels (p <0. 001) ( Table 3 ). Moreover, a tendency towards lower TG level after surgical remission was showed in comparison with baseline, although not statistically significant. Surprisingly, the level of HDL-c also showed a decrease at follow-up in remission group. The prevalence of hyperlipidemia (33. 8% vs. 20. 0%, p= 0. 049) and hypercholesterolemia was significantly decreased at follow-up (32. 3% vs. 10. 8%, p= 0. 001) whereas that of hypertriglyceridemia remained unchanged. Additionally, the level of HbA1c at follow-up was lower than that of pre-surgery. However, there was no significant change in lipid profile in six non-remission patients after surgery. As for the change rates of lipid profile and dyslipidemia status before and after surgery, the prevalence of hyperlipidemia and hypercholesterolemia was observed significantly decreased in remission group compared with the non-remission group ( Table 3 ). Out of 36 patients with preoperative hyperlipidemia, 22 patients had biochemical remission after surgery with available data on lipid profile at last follow-up, which was further classified into 2 groups according to their change of hyperlipidemia status: the improved group (n= 13, from HLP to NLP), and the persisted group (n= 9, from HLP to HLP). When comparing the baseline characteristics between the two groups ( Table 4 ), the persisted group was presented with higher baseline TC than the improved group(p= 0. 033). Baseline TG and LDL-c levels were also tended to be higher in the persisted group than in the improved group, although the difference did not reach statistical significance. However, there were no differences concerning age, BMI, disease duration, IGM, serum cortisol, plasma ACTH, the percentage of hypertension, post-surgery growth hormone deficiency (GHD), post-surgery hypogonadotropic hypogonadism (HH), and hydrocortisone replacement therapy (HRT) between the two groups. Correlation analysis showed that the higher baseline TC level was significantly associated with the persistence of hyperlipidemia after surgery (r= 0. 505, p= 0. 033) independent of age, BMI, disease duration, and preoperative serum cortisol level.
TABLE 3
Baseline and post-surgery changes in CD patients with remission or no remission at follow-up.
TABLE 4
Comparison of baseline and post-surgery characteristics of CD patients with biochemical remission after surgery presenting with improved or persisted hyperlipidemia status at last follow-up.
Discussion
The present study identified both preoperative morning serum cortisol level and impaired glucose metabolism as independent risk factors of hyperlipidemia occurrence during the active phase of CD, suggesting that IGM and the degree of hypercortisolism may together contribute to the pathogenesis of hyperlipidemia in CD.
The mechanisms of hyperlipidemia in CD are multifactorial. It is well known that glucocorticoids (GC) have complex effects on lipid metabolism, including direct and indirect GC action on lipolysis and lipogenesis, adipocytes differentiation and distribution, free fatty acid (FFA) production and turnover, VLDL synthesis and hepatic fatty accumulation ( 4 , 5 , 12 ). Specifically, GC increases both intra-adipocyte and intravascular lipolysis by activating lipoprotein lipase, leading to increased triglyceride hydrolysis in adipose tissues and turnover of FFA in the circulation ( 5 , 13 , 14 ). On the other hand, GC enhances hepatic lipogenesis and VLDL production by stimulating lipogenic enzyme activities and inhibits FFA oxidation in the liver ( 5 ). In a previous study, patients with CS had increased fatty acid synthase expression than controls owing to the suppression of AMP-activated protein kinase (AMPK) activity in visceral adipose tissue, which of interest was correlated with the severity of hypercortisolism ( 15 ). Glucocorticoid inhibition of hairy enhancer of split 1 (Hes1) gene expression that regulates hepatic production of pancreatic lipase is also involved in the pathogenesis of dyslipidemia ( 16 ). Besides, the enzyme 11β-hydroxysteroid dehydrogenase type 1 (11βHSD-1) that regulates intracellular active GC concentrations was found increased in the adipose tissue of obese humans. Transgenic mice models expressing increased 11βHSD-1 activity selectively in either adipose tissue or liver would develop visceral obesity or hepatic steatosis respectively, and both exhibited visceral obesity and the metabolic syndrome, such as insulin-resistance, hyperlipidemia and hypertension ( 17 , 18 ), which suggests that GC mediated by11βHSD-1 activity may play a significant role in adipose tissue redistribution and metabolic syndrome. Moreover, visceral obesity due to hypercortisolism in CD also plays an essential role in the determination of lipid abnormalities by promoting increased lipolysis, aberrant adipokine secretion, low-grade inflammation, and insulin resistance ( 19 , 20 ). Previous data regarding the relationship between lipid profile and the degree of hypercortisolemia is very variable. Higher serum or urine cortisol level has been shown associated with high TG, high LDL-c, and low HDL-c levels ( 6 , 21 , 22 ), while Mancini et al. showed a reverse correlation between TC and LDL-c with morning serum cortisol levels in CS ( 23 ). Nevertheless, no correlation was found between serum morning cortisol and any lipid parameters in Dhingra’s study ( 24 ). In the current study, we found a significant positive correlation between TC and morning serum cortisol level, but no significant associations between the extent of cortisol excess and any other lipid parameters. Genetic variations in the glucocorticoid receptors (GR) can affect the function of GC and lipid metabolism. In particular, N363S polymorphism related to hypersensitivity to GC was recently associated with increased TC and TG levels and total/HDL-c ratio ( 6 ). The widely existed genetic polymorphism of GR may partially explain the inconsistency in associations between cortisol level and dyslipidemia in CD. The difference might also be due to various criteria for diagnosing dyslipidemia in different studies.
Additionally, insulin resistance is a primary underlying disorder that drives lipid abnormalities. It was revealed that in CD patients the serine kinases phosphorylating serine sites on insulin receptors, such as JNK and IKK-β, are activated, which results in insulin resistance ( 25 ), and in return, insulin resistance acts synergistically with hypercortisolism to upregulate lipogenesis, causing central obesity and hepatic steatosis ( 26 ). The main abnormality related to IGM is increased assembly and secretion of VLDL, apoB, and TG ( 27 , 28 ). The Framingham Offspring Study demonstrated an association between diabetes and a higher prevalence of elevated TG and decreased HDL cholesterol ( 29 ). Inadequate glycemic control may exacerbate HDL dysfunction in patients with T2DM ( 30 , 31 ). The current data showed that hyperlipidemia was significantly associated with the 2h-BG level as well as the prevalence of diabetes DM family history in CD. Insulin resistance affects all of the TG supply pathways for VLDL assembly, resulting in increased assembly and secretion of VLDL and the consequent hypertriglyceridemia, leading to reduced HDL-cholesterol levels and increased small dense LDL (sdLDL) particles ( 32 , 33 ).
Although GC replacement therapy has been associated with increased TG, TC, and LDL concentrations in patients with hypopituitarism ( 34 ), a recent study by Choi et al. showed exogenous GC exposure has no association with lipid abnormalities ( 35 ). Of interest, in the absence of IGM, subclinical hypercortisolism does not affect lipid metabolism in patients with adrenal incidentalomas ( 36 ). The association between dyslipidemia with IGM rather than subtle GC excess suggests that GC may indirectly affect lipid metabolism by mediating glucose metabolism and insulin resistance.
In CD, hypercortisolism induces impairment of glucose metabolism by both direct and indirect effects, including stimulation of hepatic gluconeogenesis, inducement of insulin resistance by impairing insulin signaling pathway in peripheral tissues, as well as reduction of pancreatic β-cell function leading to impaired insulin secretion ( 37 , 38 ). Moreover, the enhanced intracellular and hepatic lipid accumulation and lipolysis as a consequence of hypercortisolism could in turn contribute to the development of insulin resistance ( 5 ). Mancini et al. revealed a positive correlation between fasting glycemia and the degree of cortisol excess in CS ( 23 ). However, as previously reported ( 20 ), no association between serum or urine cortisol levels and the presence of IGM or any glycemic parameters was found in the present study, suggesting that the influence of hypercortisolism on glucose metabolism might be multifactorial and indirect. Different sample size and genetic background of the studied populations may also account for the disagreement of the relationship between GC level and occurrence of IGM.
In agreement with previous studies ( 23 ), the prevalence of baseline hypertension was significantly correlated with the duration of hypercortisolism, visceral obesity, and the TG level. An independent association was detected between baseline TG and SBP in the present study, even after adjustment for other potential confounding variables, indicating hypertriglyceridemia might be a pathogenic factor for hypertension in CD. Multiple studies have demonstrated the relationship between hypertension and dyslipidemia in the non-CD population ( 39 , 40 ). In the Physicians’ Health Study, TC, non-HDL-c, and the TC/HDL-c ratios predicted the onset of hypertension in 3110 men without self-reported hypertension ( 41 ). Furthermore, a 1-SD increase in serum TG concentrations was associated with a 1. 8-fold higher risk of incident hypertension in middle-aged men ( 42 ), while statin therapy leads to a considerable reduction in SBP in hyperlipidemia patients ( 43 ). In a recent study, SBP values were found positively correlated with lipids profiles, including TC, TG, LDL-c, apolipoprotein A (apoA), and apoB in pediatric patients with CS ( 19 ).
The pathophysiological mechanisms of hypertension in CS are complex and still not well-known, in which GC excess plays a vital role by activating RAS, inhibiting vasodilatation, and exerting simulated mineralocorticoid activity ( 4 ). The increased circulating cholesterol and triglycerides have been shown to contribute to accelerated atherosclerosis ( 12 ), endothelial dysfunction ( 44 ), increased aortic stiffness ( 42 ), and reduced aortic diameter and consequently lead to high SBP ( 45 ). In this study, hypertension was found significantly correlated with atherosclerosis at the time of diagnosis of CD. Therefore, dyslipidemia could contribute to the development of hypertension in patients with CD ( 42 ). Chronic hypertension puts patients at increased risk for cardiovascular morbidity. Thus, early recognition of hyperlipidemia in CD and initiation of lipid-lowering therapy, even in the absence of hypertension, has the potential to reduce the long-term cardiovascular risk.
Most studies report an improvement in hyperlipidemia with remission of CD, although a complete normalization of lipid profile is usually not achieved ( 14 , 22 ). In a longitudinal study, LDL-c levels showed a significant decrease at 1 year following remission of CD, but levels remained higher than healthy controls ( 22 ). In a recent investigation on lipid profile in pediatric CD patients, most of the lipid parameters including TC, LDL-c, HDL-c, and TG-rich particles showed significant improvement at 1-year follow-up after CD is cured, expect for HDL and ApoA1 ( 21 ). In our study, a significant reduction in the incidence of hyperlipidemia and hypercholesterolemia was observed in patients in surgical remission compared to those in non-remission, indicating the effectiveness and necessity of surgical remission in improving lipid metabolism disorders in CD. The TC and LDL-c levels were significantly decreased at follow-up post-CD remission, whereas the TG level had no significant reduction and the prevalence of hypertriglyceridemia remained unchanged. These results confirmed that some lipid abnormalities might persist even after remission of CD, suggesting that life-long follow-up is necessary for better monitoring and control of dyslipidemia. The persistent lipid abnormalities might be attributed to the persistent visceral obesity and maintained disadvantageous adipokine profile even after hyperlipidemia has normalized, which further result in persistent increased cardiovascular risk and mortality in patients with CD with remission ( 46 ).
Although most of the lipid parameters changed towards a beneficial cardiovascular direction, the HDL-c level surprisingly showed a decrease after remission of CD. This aberrant change was also observed in a previous study reporting a decrease of HDL particles with a cure of CD ( 21 ). The worsening of the HDL-c level seems to be in accordance with variable alterations of HDL-c level in CS reported in previous studies ( 5 , 23 ). We hypothesized that this aberrant change of the HDL-c level might involve a decrease in HDL-c synthesis and an increase in cholesterol transport from HDL to other lipoproteins after the withdraw of hypercortisolism. However, the exact mechanism needs further investigation.
The odds of hyperlipidemia at follow-up were found positively associated with higher baseline TG levels in patients with CS in remission ( 47 ). In the present study, the persistence of hyperlipidemia after surgical normalization of hypercortisolism was positively associated with baseline TC levels, regardless of other potential mediating preoperative variables. The post-surgery hormonal replacement treatments due to hypopituitarism seem to have no effect on the persistent hyperlipidemia, even though subtle hypercortisolism has been suggested associated with increased metabolic abnormalities ( 45 ). Previous studies have shown that both growth hormone deficiency (GHD) and estrogen replacement therapy due to hypogonadotropic hypogonadism (HH) can cause metabolic complications, e. g. hyperlipidemia, hypertension, and increased risk of atherosclerosis ( 48 – 50 ). However, no significant impact of GHD or estrogen replacement was observed on post-surgery lipid profile recovery in our cohort. These results suggest that patients with more severe preoperative lipid disturbance may exhibit poorer postoperative lipid profile recovery. Therefore, early detection and treatment of hyperlipidemia are of paramount significance in preventing its persistence after remission.
There were several limitations to our study. First, the relatively small number of subjects and the retrospective nature of the study precludes confirmation of the causal relationships between the explored parameters and weakens the statistical power of the analysis. Besides, some clinical and laboratory assays were not routinely performed during CD evaluation; therefore, several biochemical components (e. g. insulin level) were absent in the analysis. Second, since follow-up visits were at the patients’ own expense and willingness, and some of their follow-up medical records at local hospitals were hard to require, it is difficult to achieve a sufficiently long follow-up period or fixed follow-up time points while meeting sample size requirements. In this study, the follow-up period was relatively short in some patients (median: 17. 3 months, range: 6. 0–52. 0 months) and follow-up timing was not fixed, and only 75% (78/104) of the patients enrolled at diagnosis had complete follow-up data available for post-surgery analysis. Also, some important parameters, such as blood pressure and fasting glucose, were not measured in all patients at outpatient follow-up which limited further investigation on post-surgery metabolic patterns. Third, there is no control group in this study to compare lipid abnormalities both at baseline and post-surgery. In addition, only patients who were not on lipid-lowering drugs at the time of CD diagnosis were included in this study to avoid the potential influence of the use of lipid-lowering drugs on the study of the relationship among preoperative metabolic parameters and hypercortisolism. However, in actual clinical practice, some patients may have been on lipid-lowering medication preoperatively, so their preoperative lipid metabolism and its relationship with other parameters, as well as their postoperative lipid profile recovery may differ from the results of this study.
Conclusions
In conclusion, impaired glucose metabolism and the extent of hypercortisolism are both independent risk factors of the preoperative occurrence of hyperlipidemia in patients with CD. The pattern of lipid abnormalities may persist after surgical remission, and the persisted hyperlipidemia is associated with higher baseline TC levels. These findings suggest that the clinical management of hyperlipidemia in CD patients should focus not only on normalizing hypercortisolism by surgery but also on the early identification and control of other associated risk factors, such as impaired glucose metabolism. Furthermore, this preliminary study may provide a lead to investigate biological mechanisms underlying the common link between lipid and glucose metabolism together and their roles in the regulation of blood pressure in CD.
Data Availability Statement
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.
Ethics Statement
The studies involving human participants were reviewed and approved by Institutional review board of Peking Union Medical College Hospital, Chinese Academy of Medical Sciences. Written informed consent to participate in this study was provided by the participants’ legal guardian/next of kin.
Author Contributions
XS performed the interpretation and analysis of the clinical data, wrote the main manuscript text and prepared figure and tables. MF designed the work, and critically revised it for important intellectual content. ZZ participated in analysis of the clinical data and revision of the manuscript. LL, XB, KD, YY, HZ, and RW participated in clinical management and investigation and collected the data. All authors contributed to the article and approved the submitted version.
Funding
This work was supported by the Natural Science Foundation of Beijing Municipality (grant no. 7182137).
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
References
1. Pivonello R, Isidori AM, De Martino MC, Newell-Price J, Biller BM, Colao A. Complications of Cushing’s syndrome: state of the art. Lancet Diabetes Endocrinol (2016) 4(7): 611–29. doi: 10. 1016/s2213-8587(16)00086-3
2. Witek P, Zieliński G, Szamotulska K, Witek J, Zgliczyński W. Complications of Cushing’s disease – prospective evaluation and clinical characteristics. Do they affect the efficacy of surgical treatment? Endokrynol Polska (2012) 63(4): 277–85.
3. Ferraù F, Korbonits M. Metabolic comorbidities in Cushing’s syndrome. Eur J Endocrinol (2015) 173(4): M133–57. doi: 10. 1530/eje-15-0354
4. Arnaldi G, Mancini T, Tirabassi G, Trementino L, Boscaro M. Advances in the epidemiology, pathogenesis, and management of Cushing’s syndrome complications. J Endocrinol Invest (2012) 35(4): 434–48. doi: 10. 1007/bf03345431
5. Arnaldi G, Scandali VM, Trementino L, Cardinaletti M, Appolloni G, Boscaro M. Pathophysiology of dyslipidemia in Cushing’s syndrome. Neuroendocrinology (2010) 92 Suppl 1: 86–90. doi: 10. 1159/000314213
6. Anagnostis P, Athyros VG, Tziomalos K, Karagiannis A, Mikhailidis DP. Clinical review: The pathogenetic role of cortisol in the metabolic syndrome: a hypothesis. J Clin Endocrinol Metab (2009) 94(8): 2692–701. doi: 10. 1210/jc. 2009-0370
7. Macfarlane DP, Forbes S, Walker BR. Glucocorticoids and fatty acid metabolism in humans: fuelling fat redistribution in the metabolic syndrome. J Endocrinol (2008) 197(2): 189–204. doi: 10. 1677/joe-08-0054
8. Katsiki N, Tentolouris N, Mikhailidis DP. Dyslipidaemia in type 2 diabetes mellitus: bad for the heart. Curr Opin Cardiol (2017) 32(4): 422–9. doi: 10. 1097/hco. 0000000000000407
9. Geer EB, Islam J, Buettner C. Mechanisms of glucocorticoid-induced insulin resistance: focus on adipose tissue function and lipid metabolism. Endocrinol Metab Clinics North America (2014) 43(1): 75–102. doi: 10. 1016/j. ecl. 2013. 10. 005
10. Nieman L, Biller B, Findling J, Murad M, Newell-Price J, Savage M, et al. Treatment of Cushing’s Syndrome: An Endocrine Society Clinical Practice Guideline. J Clin Endocrinol Metab (2015) 100(8): 2807–31. doi: 10. 1210/jc. 2015-1818
11. Pivonello R, De Leo M, Cozzolino A, Colao A. The Treatment of Cushing’s Disease. Endocrine Rev (2015) 36(4): 385–486. doi: 10. 1210/er. 2013-1048
12. Arnaldi G, Angeli A, Atkinson AB, Bertagna X, Cavagnini F, Chrousos GP, et al. Diagnosis and complications of Cushing’s syndrome: a consensus statement. J Clin Endocrinol Metab (2003) 88(12): 5593–602. doi: 10. 1210/jc. 2003-030871
13. van Raalte DH, Ouwens DM, Diamant M. Novel insights into glucocorticoid-mediated diabetogenic effects: towards expansion of therapeutic options? Eur J Clin Invest (2009) 39(2): 81–93. doi: 10. 1111/j. 1365-2362. 2008. 02067. x
14. Greenman Y. Management of dyslipidemia in Cushing’s syndrome. Neuroendocrinology (2010) 92 Suppl 1: 91–5. doi: 10. 1159/000314294
15. Kola B, Christ-Crain M, Lolli F, Arnaldi G, Giacchetti G, Boscaro M, et al. Changes in adenosine 5’-monophosphate-activated protein kinase as a mechanism of visceral obesity in Cushing’s syndrome. J Clin Endocrinol Metab (2008) 93(12): 4969–73. doi: 10. 1210/jc. 2008-1297
16. Lemke U, Krones-Herzig A, Berriel Diaz M, Narvekar P, Ziegler A, Vegiopoulos A, et al. The glucocorticoid receptor controls hepatic dyslipidemia through Hes1. Cell Metab (2008) 8(3): 212–23. doi: 10. 1016/j. cmet. 2008. 08. 001
17. Masuzaki H, Paterson J, Shinyama H, Morton N, Mullins J, Seckl J, et al. A transgenic model of visceral obesity and the metabolic syndrome. Sci (N Y NY)(2001) 294(5549): 2166–70. doi: 10. 1126/science. 1066285
18. Paterson J, Morton N, Fievet C, Kenyon C, Holmes M, Staels B, et al. Metabolic syndrome without obesity: Hepatic overexpression of 11beta-hydroxysteroid dehydrogenase type 1 in transgenic mice. Proc Natl Acad Sci USA (2004) 101(18): 7088–93. doi: 10. 1073/pnas. 0305524101
19. Qin L, Zhu X, Liu X, Zeng M, Tao R, Zhuang Y, et al. Evaluation of lipid profile and its relationship with blood pressure in patients with Cushing’s disease. Endocrine Connections (2018) 7(5): 637–44. doi: 10. 1530/ec-18-0010
20. Barbot M, Zilio M, Scaroni C. Cushing’s syndrome: Overview of clinical presentation, diagnostic tools and complications. Best Pract Res Clin Endocrinol Metab (2020) 34(2): 101380. doi: 10. 1016/j. beem. 2020. 101380
21. Makri A, Cheung A, Sinaii N, Remaley AT, Sampson M, Keil M, et al. Lipoprotein particles in patients with pediatric Cushing disease and possible cardiovascular risks. Pediatr Res (2019) 86(3): 375–81. doi: 10. 1038/s41390-019-0438-0
22. Giordano R, Picu A, Marinazzo E, D’Angelo V, Berardelli R, Karamouzis I, et al. Metabolic and cardiovascular outcomes in patients with Cushing’s syndrome of different aetiologies during active disease and 1 year after remission. Clin Endocrinol (2011) 75(3): 354–60. doi: 10. 1111/j. 1365-2265. 2011. 04055. x
23. Mancini T, Kola B, Mantero F, Boscaro M, Arnaldi G. High cardiovascular risk in patients with Cushing’s syndrome according to 1999 WHO/ISH guidelines. Clin Endocrinol (2004) 61(6): 768–77. doi: 10. 1111/j. 1365-2265. 2004. 02168. x
24. Dhingra A, Ganie MA, Dharmshaktu P, Chakraborty S, Jyotsna VP, Gupta N. Pattern of Lipid Abnormalities Among South Asian Indians With Cushing’s Syndrome and the Short Term Impact of Surgical Correction of Hypercortisolism. Hormone Metab Res Hormon Und Stoffwechselforschung Hormones Metabol (2019) 51(5): 309–14. doi: 10. 1055/a-0879-5122
25. Tilg H, Moschen A. Insulin resistance, inflammation, and non-alcoholic fatty liver disease. Trends Endocrinol Metabol: TEM (2008) 19(10): 371–9. doi: 10. 1016/j. tem. 2008. 08. 005
26. Vegiopoulos A, Herzig S. Glucocorticoids, metabolism and metabolic diseases. Mol Cell Endocrinol (2007) 275: 43–61. doi: 10. 1016/j. mce. 2007. 05. 015
27. Kissebah AH, Alfarsi S, Evans DJ, Adams PW. Integrated regulation of very low density lipoprotein triglyceride and apolipoprotein-B kinetics in non-insulin-dependent diabetes mellitus. Diabetes (1982) 31(3): 217–25. doi: 10. 2337/diab. 31. 3. 217
28. Adiels M, Borén J, Caslake MJ, Stewart P, Soro A, Westerbacka J, et al. Overproduction of VLDL1 driven by hyperglycemia is a dominant feature of diabetic dyslipidemia. Arteriosclerosis Thrombosis Vasc Biol (2005) 25(8): 1697–703. doi: 10. 1161/01. atv. 0000172689. 53992. 25
29. Siegel RD, Cupples A, Schaefer EJ, Wilson PW. Lipoproteins, apolipoproteins, and low-density lipoprotein size among diabetics in the Framingham offspring study. Metabolism: Clin Exp (1996) 45(10): 1267–72. doi: 10. 1016/s0026-0495(96)90246-2
30. Sánchez-Quesada JL, Vinagre I, de Juan-Franco E, Sánchez-Hernández J, Blanco-Vaca F, Ordóñez-Llanos J, et al. Effect of improving glycemic control in patients with type 2 diabetes mellitus on low-density lipoprotein size, electronegative low-density lipoprotein and lipoprotein-associated phospholipase A2 distribution. Am J Cardiol (2012) 110(1): 67–71. doi: 10. 1016/j. amjcard. 2012. 02. 051
31. Gomez Rosso L, Lhomme M, Meroño T, Dellepiane A, Sorroche P, Hedjazi L, et al. Poor glycemic control in type 2 diabetes enhances functional and compositional alterations of small, dense HDL3c. Biochim Biophys Acta Mol Cell Biol Lipids (2017) 1862(2): 188–95. doi: 10. 1016/j. bbalip. 2016. 10. 014
32. Ginsberg HN. Insulin resistance and cardiovascular disease. J Clin Invest (2000) 106(4): 453–8. doi: 10. 1172/jci10762
33. Vergès B. Pathophysiology of diabetic dyslipidaemia: where are we? Diabetologia (2015) 58(5): 886–99. doi: 10. 1007/s00125-015-3525-8
34. Filipsson H, Monson JP, Koltowska-Häggström M, Mattsson A, Johannsson G. The impact of glucocorticoid replacement regimens on metabolic outcome and comorbidity in hypopituitary patients. J Clin Endocrinol Metab (2006) 91(10): 3954–61. doi: 10. 1210/jc. 2006-0524
35. Choi HK, Seeger JD. Glucocorticoid use and serum lipid levels in US adults: the Third National Health and Nutrition Examination Survey. Arthritis Rheumatism (2005) 53(4): 528–35. doi: 10. 1002/art. 21329
36. Masserini B, Morelli V, Palmieri S, Eller-Vainicher C, Zhukouskaya V, Cairoli E, et al. Lipid abnormalities in patients with adrenal incidentalomas: role of subclinical hypercortisolism and impaired glucose metabolism. J Endocrinol Invest (2015) 38(6): 623–8. doi: 10. 1007/s40618-014-0232-0
37. Pivonello R, De Leo M, Vitale P, Cozzolino A, Simeoli C, De Martino MC, et al. Pathophysiology of diabetes mellitus in Cushing’s syndrome. Neuroendocrinology (2010) 92 Suppl 1: 77–81. doi: 10. 1159/000314319
38. Mazziotti G, Gazzaruso C, Giustina A. Diabetes in Cushing syndrome: basic and clinical aspects. Trends Endocrinol Metabol: TEM (2011) 22(12): 499–506. doi: 10. 1016/j. tem. 2011. 09. 001
39. Takiwaki M, Tomoda F, Koike T, Taki T, Inoue H, Kigawa M, et al. Increased levels of small dense low-density lipoprotein cholesterol associated with hemorheological abnormalities in untreated, early-stage essential hypertensives. Hypertension Res Off J Japan Soc Hypertension (2014) 37(11): 1008–13. doi: 10. 1038/hr. 2014. 111
40. Kim YK, Seo HS, Lee EM, Na JO, Choi CU, Lim HE, et al. Association of hypertension with small, dense low-density lipoprotein in patients without metabolic syndrome. J Hum Hypertension (2012) 26(11): 670–6. doi: 10. 1038/jhh. 2011. 86
41. Halperin RO, Sesso HD, Ma J, Buring JE, Stampfer MJ, Gaziano JM. Dyslipidemia and the risk of incident hypertension in men. Hypertension (Dallas Tex 1979)(2006) 47(1): 45–50. doi: 10. 1161/01. HYP. 0000196306. 42418. 0e
42. Laaksonen DE, Niskanen L, Nyyssönen K, Lakka TA, Laukkanen JA, Salonen JT. Dyslipidaemia as a predictor of hypertension in middle-aged men. Eur Heart J (2008) 29(20): 2561–8. doi: 10. 1093/eurheartj/ehn061
43. Strazzullo P, Kerry SM, Barbato A, Versiero M, D’Elia L, Cappuccio FP. Do statins reduce blood pressure?: a meta-analysis of randomized, controlled trials. Hypertension (Dallas Tex 1979)(2007) 49(4): 792–8. doi: 10. 1161/01. hyp. 0000259737. 43916. 42
44. de Sousa Rodrigues CF, Lira AB. Correlation between the severity of apnea and hypopnea sleep, hypertension and serum lipid and glycemic: a case control study. Eur Arch Oto-rhino-laryngol Off J Eur Fed Oto-Rhino-Laryngol Soc (EUFOS) Affiliated German Soc Oto-Rhino-Laryngol Head Neck Surg (2015) 272(6): 1509–15. doi: 10. 1007/s00405-014-3076-5
45. Lupoli R, Ambrosino P, Tortora A, Barba L, Lupoli GA, Di Minno MN. Markers of atherosclerosis in patients with Cushing’s syndrome: a meta-analysis of literature studies. Ann Med (2017) 49(3): 206–16. doi: 10. 1080/07853890. 2016. 1252055
46. Javanmard P, Duan D, Geer EB. Mortality in Patients with Endogenous Cushing’s Syndrome. Endocrinol Metab Clinics North America (2018) 47(2): 313–33. doi: 10. 1016/j. ecl. 2018. 02. 005
47. Schernthaner-Reiter MH, Siess C, Gessl A, Scheuba C, Wolfsberger S, Riss P, et al. Factors predicting long-term comorbidities in patients with Cushing’s syndrome in remission. Endocrine (2019) 64(1): 157–68. doi: 10. 1007/s12020-018-1819-6
48. Judd H, Meldrum D, Deftos L, Henderson B. Estrogen replacement therapy: indications and complications. Ann Internal Med (1983) 98(2): 195–205. doi: 10. 7326/0003-4819-98-2-195
49. Hayashi T. [Hormone replacement Up-to-date. The effect of estrogen on vascular function and atherosclerosis]. Clin Calcium (2007) 17(9): 1355–63.
50. Sesmilo G, Biller B, Llevadot J, Hayden D, Hanson G, Rifai N, et al. Effects of growth hormone administration on inflammatory and other cardiovascular risk markers in men with growth hormone deficiency. A randomized, controlled clinical trial. Ann Internal Med (2000) 133(2): 111–22. doi: 10. 7326/0003-4819-133-2-200007180-00010