Invest Clin 64(3): 329 - 337, 2023 https://doi.org/10.54817/IC.v64n3a6
Corresponding author: Hesong Ye. Jiangsu Second Chinese Medicine Hospital, The Second Affiliated Hospital of
Nanjing University of Chinese Medicine, Nanjing 210000, Jiangsu Province, China. Email: yehsjscmu@shu-edu.cn
Association of formation of urinary calculi
with blood lipid levels.
Longlong Tang, Hesong Ye, Yuan Qin, Ming Yang, Wentao Gong, Qi He, Yang Shen
and Qiyue Wang
Jiangsu Second Chinese Medicine Hospital, The Second Affiliated Hospital of Nanjing
University of Chinese Medicine, Nanjing 210000, Jiangsu Province, China.
Keywords: urinary calculi; blood lipids; correlation.
Abstract. We aimed to analyze the composition of urinary calculi and its
correlations with blood lipids such as triglycerides (TG), total cholesterol (TC),
low-density lipoprotein cholesterol (LDL-C), and high-density lipoprotein cho-
lesterol (HDL-C). Three hundred patients with urinary calculi treated from
January 2020 to July 2021 were selected retrospectively into a urinary calculi
group, while three hundred healthy individuals who received physical examina-
tion in our hospital during the same period were enrolled in a control group. Us-
ing the Spearman correlation analysis, we investigated the correlation between
the composition of urinary calculi and dyslipidemia and explored the factors
affecting urinary calculi through multivariate logistic regression analysis. The
serum levels of TG and TC were significantly higher (p<0.05), the serum HDL-
C level was significantly lower (p<0.05), while the serum LDL-C level displayed
no significant difference (p>0.05) in the urinary calculi group compared with
those in the control group. The proportion of uric acid calculi was significantly
higher in urinary calculi patients with dyslipidemia than that in those with
normal blood lipids (p<0.05). However, no significant difference was observed
in the proportions of infectious calculi and calcium calculi between urinary
calculi patients with dyslipidemia and those with normal blood lipids (p>0.05).
Dyslipidemia was positively correlated with uric acid calculi (p<0.05) but not
associated with infectious calculi or calcium calculi (p>0.05). TG was a risk
factor for urinary calculi (p<0.05). The formation of urinary calculi is closely
associated with blood lipid levels. Dyslipidemia, especially hypertriglyceride-
mia, can easily induce the formation of uric acid calculi.
330 Tang et al.
Investigación ClÃnica 64(3): 2023
Asociación de formación de cálculos urinarios con niveles
de lÃpidos en sangre.
Invest Clin 2023; 64 (3): 329 – 337
Palabras clave: cálculos urinarios, lÃpidos en sangre, correlación.
Resumen. Nuestro objetivo fue analizar la composición de los cálculos uri-
narios y sus correlaciones con los lÃpidos sanguÃneos, como los triglicéridos
(TG), el colesterol total (CT), el colesterol de lipoproteÃnas de baja densidad
(LDL-C) y el colesterol de lipoproteÃnas de alta densidad (HDL-C). Trescien-
tos pacientes con cálculos urinarios tratados desde enero de 2020 hasta julio
de 2021 fueron seleccionados retrospectivamente e incluidos en el grupo de
cálculos urinarios, mientras que trescientas personas sanas que recibieron un
examen fÃsico en nuestro hospital durante el mismo perÃodo se inscribieron en
el grupo control. La correlación entre la composición de los cálculos urinarios y
la dislipidemia se investigó mediante un análisis de correlación de Spearman, y
los factores que afectan a los cálculos urinarios se exploraron mediante un aná-
lisis de regresión logÃstica multivariable. Los niveles séricos de TG y TC fueron
significativamente más altos (p<0,05), el nivel sérico de HDL-C fue significati-
vamente más bajo (p<0,05), mientras que el nivel sérico de LDL-C no mostró
diferencias significativas (p>0,05) en el grupo los cálculos urinarios en compa-
ración con los del grupo control. La proporción de cálculos de ácido úrico fue
significativamente mayor en los pacientes con cálculos urinarios y dislipidemia
que en aquellos con lÃpidos sanguÃneos normales (p<0,05). Sin embargo, no se
observaron diferencias significativas en las proporciones de cálculos infecciosos
y cálculos de calcio entre los pacientes con cálculos urinarios con dislipidemia
y aquellos con lÃpidos sanguÃneos normales (p>0,05). La dislipidemia se corre-
lacionó positivamente con cálculos de ácido úrico (p<0,05), pero no se asoció
con cálculos infecciosos o cálculos de calcio (p>0,05). TG fue un factor de ries-
go para cálculos urinarios (p<0,05). La formación de cálculos urinarios está
estrechamente relacionada con los niveles de lÃpidos en sangre. La dislipidemia,
especialmente la hipertrigliceridemia, puede inducir fácilmente la formación
de cálculos de ácido úrico.
Received: 28-09-2022 Accepted: 17-04-2023
INTRODUCTION
Urinary calculi is one of the common
urinary system diseases, with an annually
steadily increasing prevalence rate, espe-
cially in young people, and the first attack
rate is the highest among people aged 20-
30 years old
1,2
. From a global view, urinary
calculus presents a high prevalence rate in
countries such as the United States, China,
Thailand, and the United Kingdom, but is
rare in Central America, South America,
and Africa. Epidemiological data have man-
ifested that the incidence rate of urinary
calculi is 1-5% in China, and about 25% of
such patients need to be hospitalized
3,4
. As
Risk factors for urinary calculi 331
Vol. 64(3): 329 - 337, 2023
people’s working rhythm speeds up, their
diet structure changes and their living stan-
dards improve, the incidence rate of urinary
calculi is climbing each year. The formation
of urinary calculi is exceptionally compli-
cated and closely associated with abnor-
mal lipid metabolism, insulin resistance,
hyperglycemia, hypertension, obesity, etc.
5
.
Blood lipids are essential substances for the
primary metabolism of living cells, which
widely exist in human bodies and can take
part in energy metabolism
6
. According to
a study
7
, abnormal lipid metabolism is es-
sential in forming urinary calculi. However,
the correlations between blood lipids and
urinary calculi remain unclear. Therefore,
this study analyzed the composition of uri-
nary calculi, and the correlations of urinary
calculi with blood lipids were investigated
to provide a theoretical basis for the clini-
cal prevention and treatment of urinary cal-
culi.
PATIENTS AND METHODS
General data
Three hundred patients with urinary
calculi treated in our hospital from Janu-
ary 2020 to July 2021 were selected retro-
spectively into a urinary calculi group, while
three hundred healthy individuals who re-
ceived physical examination in our hospital
during the same period were enrolled in a
control group.
Inclusion criteria: 1) patients diag-
nosed as urinary calculi by B-ultrasound,
kidney ureter bladder X-ray, intravenous py-
elography, or computed tomography urog-
raphy, 2) those whose medical history was
complete, 3) those without blood diseases,
4) those without autoimmune diseases, 5)
those with no cardiovascular diseases, and 6)
those who were informed of this study and
signed the informed consent. Exclusion cri-
teria: 1) patients complicated with dysfunc-
tion of vital organs such as heart, liver, or
lung, 2) those pregnant or breastfeeding, 3)
those complicated with a malignant tumor,
hypertension, or diabetes mellitus, 4) those
with abnormal blood coagulation, 5) those
with hyperparathyroidism, or 6) those with
cognitive dysfunction.
Methods
Age, gender, BMI, smoking history,
drinking history, and other general data of
all the subjects were recorded after admis-
sion. Five ml of fasting peripheral venous
blood was collected in the morning and
placed in an aseptic vacuum blood collec-
tion tube. After centrifugation (Beijing Era
Beili Centrifuge Co., Ltd., model: DT4-6D)
at 3,000 rpm for 15 min to separate the se-
rum, the serum levels of low-density lipo-
protein cholesterol (LDL-C), triglyceride
(TG), high-density lipoprotein cholesterol
(HDL-C) and total cholesterol (TC) were
measured using an automatic biochemistry
analyzer (Beijing Beiruida Pharmaceutical
Technology Co., Ltd., model: SR95-SUN-
MATIK-9050). The criteria for dyslipidemia
were those referred to in the Chinese Guide-
lines for the Prevention and Treatment of
Dyslipidemia in Adults (2016 Revision)
8
.
Urinary calculi samples were collected on
the day of operation, which were washed
with distilled water and dried naturally. Lat-
er, the composition of urinary calculi was
analyzed using a LUMOS stand-alone FT-IR
spectroscopy analyzer (Bruker, Germany).
Statistical analysis
The IBM SPSS 26.0 software was uti-
lized for statistical analysis. The numerical
data were expressed as n (%) and compared
by the χ
2
test between groups. The measure-
ment data were expressed as (`χ ± s) and
compared by t-test between groups. Spear-
man’s analysis was employed to analyze the
correlation between urinary calculi compo-
sition and dyslipidemia. Besides, multivari-
ate logistic regression analysis was adopted
to explore the factors affecting urinary cal-
culi. p<0.05 indicated that the difference
was statistically significant.
332 Tang et al.
Investigación ClÃnica 64(3): 2023
RESULTS
Baseline clinical data
In the urinary calculi group, there were
190 males and 110 females, aged 18-67
years old, with an average age of 45.56±5.23
years old and a body mass index (BMI) of
24.51±3.34 kg/m
2
. Two hundred of the pa-
tients had a smoking history, while 210 of
them had a drinking history. In terms of uri-
nary calculi type, there were 100 cases of
kidney calculi, 190 cases of ureteral calculi,
and ten cases of bladder calculi. In the con-
trol group, there were 189 males and 111
females, aged 18-68 years old, with a mean
age of 45.51±5.45 years old and a BMI of
24.57±3.17 kg/m
2
. Among them, 202 pa-
tients had a smoking history, while 209 had
a drinking history. No significant differences
were found in the age, gender, smoking his-
tory, BMI, drinking history and other general
data between the two groups (p>0.05).
Composition of urinary calculi
The composition analysis results of the
300 patients with urinary calculi indicated
260 cases of calcium calculi (including 102
cases of calcium oxalate - calcium oxalate
monohydrate/calcium oxalate dihydrate),
32 cases of calcium oxalate + calcium phos-
phate, 54 cases of calcium oxalate + hydroxy-
apatite, 54 cases of calcium oxalate + uric
acid, and 18 cases of calcium oxalate + uric
acid + calcium phosphate, 51 cases of infec-
tious calculi (including 23 cases of hydroxy-
apatite + calcium oxalate, 14 cases of mag-
nesium ammonium phosphate + calcium
oxalate, four cases of hydroxyapatite + mag-
nesium ammonium phosphate, two cases of
ammonium urate, and eight cases of magne-
sium ammonium phosphate + uric acid), and
28 cases of uric acid calculi (including ten
cases of uric acid calculi and 18 cases of uric
acid + magnesium ammonium phosphate).
Serum levels of TG, HDL-C, TC and LDL-C
The serum levels of TG and TC were
significantly higher, while the serum HDL-
C levels were significantly lower in urinary
calculus group than those in control group,
showing statistically significant differences
(p<0.05). However, the serum LDL-C lev-
els in the urinary calculus group displayed
no statistically significant differences in
comparison with those in control group
(p>0.05) (Fig. 1).
Multivariate logistic regression analysis
results of factors affecting formation
of urinary calculi
Multivariate logistic regression analysis
was performed by incorporating the factors
with significant differences above, revealing
that TG was a risk factor for the formation of
urinary calculi (p<0.05) (Table 1).
Composition of calculi in urinary calculi
patients with normal blood lipids
and dyslipidemia
The proportion of uric acid calculi in
urinary calculi patients with dyslipidemia
was significantly higher than in those with
normal blood lipids, showing a statistically
significant difference (p<0.05). However,
there were no statistically significant differ-
ences in the proportions of infectious calculi
and calcium calculi between urinary calculi
patients with dyslipidemia and those with
normal blood lipids (p>0.05) (Table 2).
Correlation between the composition
of urinary calculi and dyslipidemia
Dyslipidemia was positively correlated
with uric acid calculi (p<0.05), but not as-
sociated with infectious calculi or calcium
calculi (p>0.05) (Table 3).
DISCUSSION
The reasons for the formation of urinary
calculi are complicated, and are associated
with various factors. According to a study
9
,
hyperglycemia, hypertension and abnormal
lipid metabolism are risk factors for the for-
mation of urinary calculi, and abnormal lipid
metabolism is an important contributor to
Risk factors for urinary calculi 333
Vol. 64(3): 329 - 337, 2023
Fig. 1. Serum levels of TG, HDL-C, TC and LDL-C.
Table 1
Composition of calculi in urinary calculi patients with normal blood lipids and dyslipidemia (n(%)).
Group n Infectious calculi Calcium calculi Uric acid calculi
Normal blood lipids 210 39 (18.57) 180 (85.71) 8 (3.81)
Dyslipidemia 90 12 (13.33) 80 (88.89) 20 (22.22)
χ
2
1.225 0.550 25.241
P 0.268 0.459 <0.001
Tabla 2
Correlation between composition of urinary
calculi and dyslipidemia.
Composition of urinary
calculi
Dyslipidemia
r p
Infectious calculi 0.082 0.647
Calcium calculi 0.056 0.834
Uric acid calculi 0.678 <0.001
334 Tang et al.
Investigación ClÃnica 64(3): 2023
the formation of urinary calculi, which can
increase the risk of urinary calculi by 25-
30%. A previous study
10
suggested that el-
evated blood lipid levels will induce rising
blood viscosity, leading to atherosclerosis
(AS), affecting renal blood flow, and thereby
facilitating the deposition of lithogenic sub-
stances in the blood to form calculi. The re-
sults of this study manifested that the serum
levels of TG and TC were remarkably higher.
In contrast, serum HDL-C level was dramati-
cally lower in the urinary calculus group than
those in the control group. Still, the serum
LDL-C levels were not significantly different
between the two groups, which was consis-
tent with the study results of Besiroglu et al.
11
. These findings suggest that the formation
of urinary calculi is associated with dyslipid-
emia. Moreover, the results of multivariate
logistic regression analysis demonstrated
that TG was a risk factor for urinary calculi,
implying that dyslipidemia, especially hyper-
triglyceridemia, is more prone to the forma-
tion of urinary calculi. Hence, controlling
blood lipids has important clinical signifi-
cance for the prevention of urinary calculi.
For the 300 urinary calculi patients en-
rolled in this study, the high incidence age
was 40-50 years old, with more males than
females (the male-to-female ratio was 1.73).
By analyzing the composition of urinary cal-
culi, it was found that there were 260 cases
of calcium calculi, 51 cases of infectious
calculi, and 28 cases of uric acid calculi. It
can be inferred that calcium calculi were
the major components of calculi in the 300
patients. It is probably because the dietary
structure of residents in this area is dominat-
ed by seafood, meat, and other high-protein
and high-cholesterol foods. Excessive intake
of such foods can result in the elevation of
blood lipids and increased endogenous acid
metabolites in urine, which boosts the ex-
cretion of urinary calcium, calcium oxalate,
and uric acid, reduces citrate excretion, and
lowers the reabsorption of calcium in urine,
thereby inducing more calcium oxalate cal-
culi. Among the 300 patients with urinary
calculi in this study, the proportion of pa-
tients with infectious calculi was next only
to those with calcium calculi; most were
female. Infectious calculi are the results of
infection caused by urease-producing bac-
teria in urine, and the major components
include magnesium ammonium phosphate,
apatite and so on
12
. It has been pointed out
in a study
13
that urinary tract infection is
one of the most common pathogenic fac-
tors of female urinary calculi, and the inci-
dence rate of upper urinary tract infectious
calculi in female is three times that in men.
In the present study, uric acid calculi were
Table 3
Logistic regression analysis results of factors affecting urinary calculi.
Variable Partial regression
coefficient
Standard
error
Wald P 95% CI OR
Gender -0.242 0.179 1.562 0.983 0.431-0.902 0.872
Age 0.243 0.154 1.872 0.871 0.672-1.325 1.128
BMI -0.319 0.147 4.234 0.643 0.542-0.927 0.743
Smoking history 0.156 0.182 1.784 0.743 0.783-1.221 1.209
Drinking history 0.257 0.211 1.673 0.683 1.092-2.532 1.392
TG 0.811 0.305 12.298 0.004 1.547-5.092 2.345
LDL-C 0.041 0.098 0.345 0.823 0.811-1.243 1.112
HDL-C 0.209 0.174 1.205 0.645 0.745-1.562 1.532
TC 0.227 0.172 1.782 0.711 0.943-2.093 1.342
Risk factors for urinary calculi 335
Vol. 64(3): 329 - 337, 2023
the least common among the 300 patients
with urinary calculi. Uric acid is not only the
major composition of uric acid calculi, but
also involved in the formation of calculi com-
posed of other elements. Hyperuricemia-in-
duced calculi are co-formed by a variety of
components under different internal envi-
ronments
14
. It has been revealed in a study
15
that patients with uric acid calculi have
higher incidence rates of diabetes mellitus,
poor glucose tolerance, and hypertriglyc-
eridemia than normal people. The results of
this study also demonstrated that the pro-
portion of uric acid calculi in urinary calculi
patients with dyslipidemia was dramatically
higher than that in those with normal blood
lipids. Still, there was no significant differ-
ence in the proportions of infectious calculi
and calcium calculi between urinary calculi
patients with dyslipidemia and those with
normal blood lipids.
This suggested that dyslipidemia can
easily lead to the formation of urinary calcu-
li, especially uric acid calculi, which was fur-
ther confirmed by the Spearman correlation
analysis in this study. It is because elevated
blood lipid levels can lead to lipid deposi-
tion, which damages the tubular excretory
function, thus resulting in rising uric acid
levels. Meanwhile, increased uric acid levels
reduce lipoprotein esterase activity and TG
decomposition. As a result, the blood TG lev-
el rises. In addition, high uric acid can cause
increased excretion of urine, rising uric acid
concentration in urine, and decreased urine
PH, so it is more likely to induce the forma-
tion of uric acid calculi under the action of
multiple factors
16-18
. Uric acid can reduce
the protective activity of inhibitors against
calcium oxalate crystal formation in urine,
allowing the formation of calcium oxalate
crystals and aggregation into stones. There-
fore, hyperuricemia is related to uric acid-in-
duced heterogeneous nucleation of calcium
oxalate crystals
19
.
Hence, in clinical treatment of urinary
calculi, besides calculus treatment, atten-
tion should be paid to regulating the me-
tabolism level in the body, effective control
of blood lipids, reasonable diet, and more
exercise, so as to lower the risk of recurrent
urinary calculi.
In summary, the formation of urinary
calculi is closely associated with blood lipid
levels. Dyslipidemia, especially hypertriglyc-
eridemia, can easily lead to the formation of
uric acid calculi. Controlling blood lipids has
important clinical significance for the pre-
vention of urinary calculi. Regardless, this
study is limited. This is a single-center ret-
rospective study with a small sample size, so
the results may be biased. In the future, we
will perform multicenter prospective studies
with larger sample sizes to clarify the spe-
cific mechanism.
Funding
None.
Conflicts of interest
The authors reported no potential con-
flict of interest.
ORCID numbers
• Longlong Tang (LT):
0000-0002-9951-3257
• Hesong Ye (HY):
0000-0002-8303-6468
• Yuan Qin (YQ):
0000-0003-1257-3984
• Ming Yang (MY):
0000-0002-8688-3611
• Wentao Gong (WG):
0000-0002-8891-0476
• Qi He (QH):
0000-0003-1987-0949
• Yang Shen (YS):
0000-0002-6329-9826
• Qiyue Wang (QW):
0000-0002-6593-9145
336 Tang et al.
Investigación ClÃnica 64(3): 2023
Authors’ contribution
LT and HY designed the study; YQ, MY
and WG conceived and supervised the study;
QH and YS performed and analyzed the ex-
periments; QW drafted the paper. All authors
read and approved the final manuscript.
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