Metastatic malignancies and the effect on arterial stiffness and blood pressure levels: the possible role of chemotherapy.

BACKGROUND: The aim of the prospective study was to evaluate blood pressure (BP) and the arterial stiffness before and after chemotherapy in three subgroups of patients with metastatic colorectal, renal cell, and gastrointestinal carcinoma and exploit, if possible, the effect of chemotherapy and biological agents in the event of cardiotoxicity.
METHODS: A total of 171 patients were included in the study: 60 with kidney cancer, 18 with gastrointestinal stromal tumors (GISTs), and 93 with metastatic colorectal cancer. All patients were subjected to full clinical and laboratory evaluation before and after chemotherapy. Arterial-stiffness indices were assessed before the initiation and after the completion of chemotherapy by means of pulse wave velocity (PWV; Complior) and augmentation index (AIx; SphygmoCor).
RESULTS: Patients in all three cancer cohorts exhibited significantly (P<0.001) higher levels of carotid-radial PWV, carotid-femoral PWV, and AIx postchemotherapy, which remained significant after adjustment for BP and body-mass index. AIx exhibited greater change in the bowel-cancer cohort compared to the kidney and GIST cohorts (median 3.6, 1.75, and 1.4, respectively; P<0.001), which remained significant after adjustment for BP and body-mass index. Multiple regression analysis showed that patients with higher baseline systolic BP, diastolic BP, ejection fraction, and carotid-femoral PWV exhibited smaller differences postchemotherapy, while AIx75 baseline levels showed no difference postchemotherapy.
CONCLUSION: There is a clear burden in arterial stiffness in patients under chemotherapy for kidney, GIST, and metastatic colorectal cancer, irrespective of BP and other confounders.

Introduction

Cancer and cardiovascular disease (CVD) are two of the leading causes of worldwide mortality.1 Cancer patients may develop CVD secondarily to chemotherapy cardiotoxicity. Recent efforts in cardio-oncology have begun to revise the focus toward identifying CVD early in patients suffering from malignancies, as well as the potential cardiotoxicity of chemotherapy.2,3 According to the multiple-hit hypothesis, patients with cancer are exposed to a number of events that together make them more prone to reduced CV reserves, development of CVD, and thus death.4 Heart disease following chemotherapy may be the result of either direct CV damage caused by the regime itself or induced atherosclerosis due to cancer treatment-related CV risk factors.5

Colorectal cancer is the second-most common type of malignancy in Europe, whereas 15%–25% of newly diagnosed patients have metastatic disease at diagnosis. The disease can be recurrent or lead to distant metastases in up to 50% of all cases.6,7 Survival for patients with metastatic colorectal cancer has overall increased rapidly in the last 20 years, largely due to advances in systemic chemotherapy approaches with newer regimes and the introduction of biological agents.8,9 However, the adverse effects of these biological agents, especially in the CV system, have not been fully exploited.

Sunitinib and sorafenib are tyrosine-kinase inhibitors (TKIs) of growth factor receptors, the most important of which are VEGF, PDGF, and Kit, and these are widely used for the treatment of metastatic renal cell carcinoma.10,11 Even though these biological agents are implicated in cardiac toxicity, the nature of myocardial damage from TKI treatment has not yet been extensively investigated, with controversial results from studies regarding the possible mechanisms involved and the type of provoked cardiotoxicity.

Imatinib is extremely effective in patients with advanced gastrointestinal stromal tumors (GISTs) through inhibition of the Kit kinase; however, previous data demonstrated that imatinib can lead to significant cardiac dysfunction when administered to mice at clinically relevant dosages.12 Studies have reported low incidence of clinically important heart failure in patients with GISTs treated with imatinib.13,14 A clear association between imatinib and cardiac toxicity is yet to be confirmed. The aim of the present prospective study was to evaluate blood pressure (BP), ejection fraction (EF), and arterial stiffness before and after chemotherapy in three subgroups of patients with metastatic colorectal, renal cell, and gastrointestinal carcinoma and exploit if possible the effect of chemotherapy and biological agents in the event of cardiotoxicity.

Methods

The study comprised 171 patients who were divided in to three groups based on the underlying malignancy: 60 with kidney cancer, 18 with GISTs, and 93 with metastatic colorectal cancer. The recruitment of the patients started in 2010 and finished in 2015. The study protocol was revised and approved in 2010 by the Ethics Committee of Hippokration Hospital, Athens, Greece, where the study was conducted. All patients in the study provided written informed consent prior to enrollment.

Full clinical and laboratory evaluation was carried out to exclude patients with recent (<6 months) cerebrovascular events, coronary artery disease, ischemic or nonischemic heart failure, ventricular arrhythmia, sinus bradycardia (<55 beats/minute), sinus tachycardia (>100 beats/minute), and atrioventricular conduction disturbance. Blood samples were collected from the antecubital vein between 8 and 10 am, with the patient in the sitting position for at least 10 minutes and at least after an overnight fast. All tests were conducted in the same laboratories using the criteria of the World Health Organization.

Cardiovascular evaluation

Prior to initiation of chemotherapy and immediately after its completion, all patients were subjected to full CV evaluation.

Blood pressure evaluation

The diagnosis of arterial hypertension was made based on either systolic BP (SBP; >140 mmHg) or diastolic BP (DBP; >90 mmHg) levels on three visits 1 week apart, and mean values were calculated. A 2-week washout period preceded measurement for every patient already receiving antihypertensive treatment. In each visit, BP was measured three times with the patient resting comfortably with back supported in the sitting position after a relaxation period of 10–15 minutes. A mercury sphygmomanometer was used for all measurements with an appropriately sized cuff each time. Twenty-four-hour ambulatory BP monitoring (Spacelabs healthcare, Snoqualmie, WA, USA) was carried out whenever considered appropriate.

Measurement of arterial properties

Hemodynamic measurements were conducted in the morning in a special room with stable temperature. Subjects were requested to abstain from caffeine, smoking, and alcohol for at least 12 hours before arterial property assessment was performed. SBP, DBP, and heart rate were measured three times in both arms with an automatic mercury sphygmomanometer (M4-I; Omron, Kyoto, Japan).

We used a validated commercially available system (SphygmoCor; AtCor Medical, Sydney, Australia), which uses the principle of applanation tonometry and appropriate acquisition and analysis software for noninvasive recording and analysis of the arterial pulse. High-fidelity micromanometry was used on the nondominant hand’s radial artery and gentle pressure applied. After acquiring 20 waveforms, the software performed the analysis, and augmentation index (AIx) values and ascending aortic pressure were obtained.

AI values of the central waveform were measured as indices of wave reflection. AI was defined as augmented pressure divided by pulse pressure and expressed as a percentage. Aortic pulse-pressure velocity was derived by calculating the time between the foot of the pressure wave and the inflection point. Higher AI levels suggest increased wave reflection peripherally and/or earlier return of the reflected wave, due to increased pulse wave velocity (PWV; because of increased arterial stiffness) and vice versa. Considering the potential effect of heart rate on AI, all values were automatically corrected for heart rate with SphygmoCor software (AI corrected for heart rate [AIx75]).15,16

PWV is the velocity at which the arterial pulse propagates through the circulation, and is, by definition, the distance traveled (Δx) by the wave divided by time (Δt) that allows the wave to travel that distance. Speed is determined from geometric and elastic properties of the arterial wall. For the calculation of carotid–femoral PWV (PWVc-f), pulse-transit time was measured, as well as the distance traveled between two recording sites (PWV = distance [m]/transit time [seconds]) with the Complior device (DuPont, Wilmington, De, USA). Two PWs were measured simultaneously at two sites (at the base of the neck for the common carotid and over the right-femoral artery) with two transducers. The distance was defined as distance from suprasternal notch to femoral artery minus distance from carotid artery to suprasternal notch. This is generally considered a simple noninvasive technique with good reproducibility. The European Society of Hypertension states that PWV >10 m/s can be considered an independent marker of end-organ damage, however there is still no universal agreement on fixed PWV-threshold values.17,18

Other measurements

All patients had a baseline electrocardiogram and a repeat one after the completion of chemotherapy. Baseline echocardiographic studies were performed prior to and after the end of chemotherapy cycles. Standard M-mode, two-dimensional, and Doppler images were obtained during breath-hold at end expiration and measurements obtained from the mean of three consecutive beats. Left ventricular systolic and diastolic functions were assessed pre- and postchemotherapy. Echocardiographic studies were performed in the cardiology department by the same operator each time. Tumor markers specific for each malignancy were also assessed before and after the last cycle of chemotherapy.

Chemotherapy

Sixty patients with kidney cancer were included in the study, 49 of whom received treatment with sunitinib 50 mg for six cycles and eleven with pazopanib 800 mg for six cycles. Eighteen patients with GISTs received treatment with imatinib 400 mg for six cycles. Finally, 93 patients with metastatic colorectal cancer received treatment with panitumumab–oxaliplatin-based chemotherapy (n=44), panitumumab–irinotecan-based chemotherapy (n=28), and panitumumab–capecitabine-based chemotherapy (n=21) for six to eight cycles. A detailed description of the treatment regimen in each group is presented in Table 1.

Table 1

Treatment regimen by cancer type

Cancer type	Drug	n	Number of cycles median (range)	Dose (mg) median (range)
Kidney	Sunitinib	49	6 (3–6)	50 (25–50)
	Pazopanib	11	6 (2–6)	800 (400–800)
GIST	Imatinib	18	6 (6–6)	400 (400–400)
Bowel	Panitumumab	93	8 (3–8)	530 (250–900)
	Oxaliplatin	44	8 (4–8)	190 (140–480)
	Irinotecan	28	8 (6–8)	343 (240–410)
	Capecitabine	21	6 (3–8)	1,300 (200–2,000)

Abbreviation: GIST, gastrointestinal stromal tumor.

Statistical analysis

Mean (SD), median, and range are used for presenting continuous variables, while categorical variables are presented as frequencies. To evaluate changes in parameters of interest after chemotherapy compared to baseline, the Wilcoxon signed-rank test was used, while for examining differences in these parameters among the three cancer groups, the Kruskal–Wallis test was used. Differences in study parameters among the three cancer types, adjusting for sex, body-mass index (BMI), SBP, and DBP, were assessed using an analysis of covariance model. Finally, for parameters of interest, multiple linear regression analysis was performed. For each of the parameters, the difference (after – before chemotherapy) was used as the dependent variable, while cancer type, sex, BMI, and parameter baseline values were used as independent variables. Parameters examined were SBP (mmHg), DBP (mmHg), AIx75 (%), PWVc-f (m/second), and carotid–radial PWV (PWVc-r; m/second). Additionally, within the bowel cancer subgroup, separate analyses were also performed based on the treatment regimen administered: oxaliplatin-based, irinotecan-based, and capecitabine-based. All statistical analyses were performed using R statistical software. Statistical significance was set at P=0.05 (two-sided).

Results

The study cohort comprised 171 patients divided into three groups according to the underlying malignancy: 60 with kidney cancer, 18 with GISTs, and 93 with metastatic colorectal cancer. Table 1 presents the baseline characteristics of the patients. Hemodynamic measurements and basic laboratory results pre- and postchemotherapy are presented in Table 2. Patients with kidney cancer had no significant change in either SBP or DBP levels after chemotherapy, whereas there was a significant change in EF (59.8% vs 57.8%, P=0.001), AIx75 (19.03% vs 20.9%, P<0.001), PWVc-r (721 m/second vs 7.9 m/second, P<0.001), and PWVc-f (7.3 m/second vs 8.1 m/second, P<0.001). Patients with GIST had no significant change is SBP, DBP, or EF postchemotherapy; however, AIx75, PWVc-r, and PWVc-f exhibited significant increases postchemotherapy (17.5% vs 18.7%, P=0.007; 7.7 m/second vs 8.3 m/s, P<0.001; 7.4 m/second vs 8.2 m/s, P<0.001; respectively). Finally, patients with metastatic colorectal cancer had significant changes in SBP (P=0.007), EF (P=0.007), and AIx, PWVc-r, and PWVc-f (17.2% vs 21.8%, P<0.001; 7.7 vs 8.6 m/second, P<0.001; 7.6 m/second vs 8.4 m/second, P<0.001; respectively). No significant change was noted in DBP (Table 3).

Table 2

Patient baseline characteristics

Characteristics	Entire cohort(n=171)	Kidney(n=60)	GIST(n=18)	Bowel(n=93)
Age (years)
Mean (SD)	62.9 (10.7)	57.9 (10.0)	67.4 (6.7)	65.2 (10.7)
Median	65	55.5	68.5	67
Range	29–80	38–75	54–79	29–80
Sex
Male	124 (72.5%)	42 (70%)	11 (61.1%)	71 (76.3%)
Female	47 (27.5%)	18 (30%)	7 (38.9%)	22 (23.7%)
Surgery
Inoperable	102 (59.6%)	13 (21.7%)	18 (100%)	89 (95.7%)
Operable	69 (40.4%)	47 (78.3%)	–	4 (4.3%)
Waist:hip ratio
Mean (SD)	0.88 (0.06)	0.89 (0.05)	0.86 (0.06)	0.88 (0.07)
Median	0.9	0.9	0.88	0.9
Range	0.7–0.95	0.76–0.95	0.70–0.94	0.70–0.95
Body-mass index
Mean (SD)	27.3 (6.5)	26.8 (6.0)	25.2 (7.7)	28 (6.5)
Median	27.8	26.4	24.9	28.5
Range	14.3–45.7	15.4–42.5	15.5–45.7	14.3–42.5
Cycles of chemotherapy
Mean (SD)	6.43 (1.5)	5.5 (1.2)	6.0 (–)	7.1 (1.5)
Median	6	6	6	8
Range	2–8	2–6	6–6	3–8

Abbreviation: GIST, gastrointestinal stromal tumor.

Table 3

Selected study parameters before and after chemotherapy by cancer type

Parameters	Kidney (n=60)		GIST (n=18)		Bowel (n=93)
	Before	After	Before	After	Before	After
SBP (mmHg)
Mean (SD)	134.2 (17.4)	134.6 (18.9)	126.5 (12.7)	129.8 (15.8)	137.3 (12.3)	133.5 (11.7)
Median	135	130	121.5	130	140	135
Range	105–169	100–178	110–146	105–150	110–160	105–156
DBP (mmHg)
Mean (SD)	72.6 (8.9)	70.0 (5.8)	72.6 (7.6)	74.4 (9.7)	73.4 (8.3)	72.9 (8.2)
Median	74.5	70	70	70	70	70
Range	60–87	60–82	65–90	65–98	60–90	60–98
Pulse
Mean (SD)	69.5 (6.3)	71.6 (6.2)	72.3 (8.1)	72.8 (9.0)	71.6 (6.9)	73.3 (7.0)
Median	70	70	71	70.5	70	73
Range	52–86	52–80	55–92	60–96	55–92	60–96
EF (%)
Mean (SD)	59.8 (3.4)	57.8 (4.3)	58.1 (4.6)	57.5 (4.9)	59.1 (3.6)	58.4 (4.0)
Median	60	58	60	60	60	60
Range	55–65	40–65	50–65	45–65	50–65	45–65
AIx75 (%)
Mean (SD)	19.03 (2.42)	20.9 (2.8)	17.5 (2.2)	18.7 (2.8)	17.2 (2.7)	21.8 (4.4)
Median	18.95	21.3	17.3	18	17.2	21.5
Range	14.5–25.2	15.6–28.6	14.3–21.3	14.6–24	12.5–28	14.5–33
PWVc-r (m/s)
Mean (SD)	7.2 (0.5)	7.9 (0.7)	7.7 (0.8)	8.3 (1.0)	7.7 (0.7)	8.6 (1.0)
Median	7.2	7.9	7.7	8.1	7.6	8.5
Range	6.2–7.9	6.5–9.2	6.5–9.2	6.9–10.6	6.5–10.0	6.9–11.4
PWVc-f (m/s)
Mean (SD)	7.3 (0.7)	8.1 (0.7)	7.4 (0.6)	8.2 (0.6)	7.6 (0.6)	8.4 (0.6)
Median	7.2	8	7.3	8	7.5	8.3
Range	5.6–8.9	6.5–9.5	6.5–8.6	7.2–9.2	6.3–9.5	7.2–10.7
ESR
Mean (SD)	11.8 (10.7)	12.4 (12.0)	7.6 (2.1)	9.1 (2.7)	7.7 (2.9)	7.3 (2.6)
Median	10	10	7	9	7	7
Range	5–55	4–95	5–12	5–15	5–15	5–15
CRP
Mean (SD)	5.8 (3.3)	7.0 (4.6)	5.5 (1.0)	5.6 (0.9)	6.1 (7.6)	5.5 (2.9)
Median	5.3	6.1	5.3	5.3	5	5
Range	4–30	4–40.5	4.3–8	4.3–7.5	3.0–77.2	3–30
Neutrophils
Mean (SD)	6.7 (4.8)	4.9 (3.0)	5.7 (2.1)	4.3 (2.0)	5.5 (3.1)	4.3 (2.3)
Median	5.3	4.3	5.4	4	4.9	4
Range	2.4–28.2	1.2–15.6	1.8–8.9	1.2–8.1	1.6–17.3	1.2–12.5
Hb
Mean (SD)	12.2 (1.3)	11.4 (1.9)	12.3 (1.2)	11.0 (1.2)	12.8 (1.7)	11.6 (1.9)
Median	12.3	11	12.3	10.8	12.6	11.5
Range	9.1–14.8	7.5–15.6	10.6–14.6	8.6–13	9.1–17.6	7.9–15
Plt
Mean (SD)	253.3 (117.0)	230.1 (83.8)	270.3 (126.8)	203.9 (55.4)	259.4 (102.1)	229.9 (53.2)
Median	240	215	247.5	196.5	236	219
Range	116–729	110–446	145–729	145–350	124–729	130–350
CrCl
Mean (SD)	58.4 (11.9)	58.1 (11.7)	63.2 (10.9)	63.0 (9.9)	64.4 (12.4)	60.2 (18.0)
Median	58	56.5	59	62	60	60
Range	30–90	31–86	50.2–89	51.3–86	50.7–112	1.1–112
Cr
Mean (SD)	1.3 (0.4)	1.3 (0.4)	1.1 (0.2)	1.2 (0.2)	1.0 (0.2)	1.2 (1.0)
Median	1.2	1.3	1.1	1.2	1	1
Range	0.8–2.6	0.8–2.6	0.8–1.5	0.8–1.5	0.6–1.5	0.6–6
Bil
Mean (SD)	0.7 (0.4)	0.8 (0.4)	0.6 (0.3)	0.7 (0.3)	0.6 (0.4)	0.8 (0.4)
Median	0.6	0.6	0.6	0.6	0.5	0.7
Range	0.3–1.6	0.3–2.2	0.3–1.6	0.4–1.5	0.1–2.5	0.1–2.2
SGOT
Mean (SD)	24.2 (19.8)	34.0 (23.4)	20.5 (9.8)	21.9 (5.3)	24.2 (12.8)	22.8 (8.1)
Median	20	25	16	21.5	20	21
Range	10–125	14–120	10–42	15–32	10–86	10–38
SGPT
Mean (SD)	26.0 (24.4)	37.3 (30.9)	17.6 (5.2)	24.8 (6.7)	25.4 (18.0)	25.9 (9.2)
Median	20	28	16	24.5	17	28
Range	12–166	13–175	12–31	15–36	10–84	12–55
ALP
Mean (SD)	108.4 (47.9)	105.1 (42.0)	79.4 (23.4)	82.8 (21.4)	156.7 (155.8)	135.6 (95.7)
Median	98	93.5	78.5	77.5	111	110
Range	68–352	54–295	42–121	52–124	42–926	11–473
CEA
Mean (SD)	1.5 (1.6)	1.5 (1.6)	1.2 (0.4)	1.2 (0.3)	98.2 (427.0)	59.2 (149.1)
Median	1.2	1	1	1	7.2	5
Range	0.5–10	0.5–10	0.9–2.3	0.9–2	0.6–4,011.7	0.5–1,097

Abbreviations: AIx75, augmentation index (heart rate-corrected); ALP, alkaline phosphatase; Bil, bilirubin; CEA, carcinoembryonic antigen; Cr, creatinine; CrCl, Cr clearance; CRP, c-reactive protein; DBP, diastolic blood pressure; EF, ejection fraction; ESR, erythrocyte-sedimentation rate; GIST, gastrointestinal stromal tumor; Hb, hemoglobin; Plt, platelet; PWV, pulse wave velocity; PWVc-f, carotid–femoral PWV; PWVc-r, carotid–radial PWV; SBP, systolic BP; SGOT, serum glutamic-oxaloacetic; SGPT, serum glutamic pyruvic transaminase.

In Table 4, differences in SBP, DBP, EF, AIx, PWVc-r, and PWVc-f among the three cancer groups are shown. After adjustment for sex, BMI, SBD, and DBP, a significant difference was exhibited among the three cancer types in AIx75 (P<0.001), PWVc-r (P<0.001), and PWVc-f (P=0.022) values at baseline. Comparing the differences (after – before chemotherapy) among the three cancer groups, there were no significant differences in DBP, PWVc-r, or PWVc-f. However, SBP, EF, and AIx exhibited different mean changes in the three cancer subgroups. More specifically, AIx exhibited greater change in the bowel cancer cohort compared to the kidney and GIST cohorts (median 3.6, 1.75 and 1.4, respectively; P<0.001). Finally, multiple regression analysis was performed with SBP, DBP, EF, AIx75, PWVc-r, and PWVc-f values before and after chemotherapy (Table 5), which showed that patients with higher baseline SBP, DBP, EF, and PWVc-f values exhibited smaller differences post chemotherapy, while AIx75 baseline levels were not affected postchemotherapy (Table 6).

Table 4

Differences in SBP, DBP, EF, AIx75, PWVc-r, and PWVc-f before and after chemotherapy in the total cohort and by cancer type

Status	Median (range)			P-valuea	Adjusted P-value
	Kidney (n=60)	GIST (n=18)	Bowel (n=93)
Before chemotherapy
SBP	135 (105–169)	121.5 (110–146)	140 (110–160)	0.013	0.012b
DBP	74.5 (60–87)	70 (65–90)	70 (60–90)	0.83	0.84b
EF	60 (55–65)	60 (50–65)	60 (50–65)	0.34	0.16b
AIx75	18.95 (14.5–25.2)	17.3 (14.3–21.3)	17.2 (12.5–28)	<0.001	<0.001c
PWVc-r	7.15 (6.2–7.9)	7.65 (6.5–9.2)	7.6 (6.5–10)	<0.001	<0.001c
PWVc-f	7.2 (5.6–8.9)	7.25 (6.5–8.6)	7.5 (6.3–9.5)	0.018	0.022c
Difference postchemotherapy
SBP	0 (−25 to 33)	4.5 (−13 to 33)	−5 (−40 to 15)	0.054	0.021b
DBP	−3.5 (−24 to 17)	2 (−10 to 15)	0 (−25 to 15)	0.23	0.15b
EF	0 (−20 to 5)	0 (−5 to 5)	0 (−5 to 5)	0.026	0.029b
AIx75	1.75 (−1 to 11)	1.4 (−1.7 to 5.7)	3.6 (0.4–17.2)	<0.001	<0.001c
PWVc-r	0.6 (−0.4 to 2.2)	0.4 (0.1–1.4)	0.7 (0–4.2)	0.09	0.085c
PWVc-f	0.7 (−0.4 to 2.9)	0.7 (0.1–1.5)	0.8 (−0.1 to 2.4)	0.93	0.81c

Notes: Values in bold denote significance (P<0.05). Patients with metastatic colorectal cancer were divided into subgroups according to the type of chemotherapy they received: 44 oxaliplatin-based chemotherapy, 28 irinotecan-based chemotherapy, and 21 capecitabine-based chemotherapy. Further analysis of central hemodynamics was performed on the three subgroups, and results are presented in Table 5. Comparison of differences among the three subgroups of chemotherapy showed no significant difference between AIx and PWVc-r; however, PWVc-f exhibited higher mean change in the irinotecan subgroup compared to oxaliplatin and capecitabine in the adjusted model (0.95 [0.2–2.4] vs 0.8 [−0.1 to 1.6] vs 0.5 [0.1–1.7], P=0.024, respectively).

Kruskal-Wallis p;

p-value estimated using ANCOVA with gender and BMI as covariates;

p-value estimated using ANCOVA with gender, BMI, SBP (at baseline) and DPB (at baseline) levels as covariates.

Abbreviations: AIx75, augmentation index (heart rate-corrected); DBP, diastolic blood pressure; EF, ejection fraction; PWV, pulse wave velocity; PWVc-f, carotid–femoral PWV; PWVc-r, carotid–radial PWV; SBP, systolic BP; GIST, gastrointestinal stromal tumor.

Table 5

Differences in SBP, DBP, EF, AIx75, PWVc-r, and PWVc-f before and after chemotherapy in the subgroup of bowel cancer patients by treatment regimen

Variables	Median (range)		P-value*
	Before	After
Overall (n=93)
SBP	140 (110–160)	135 (105–156)	0.007
DBP	70 (60–90)	70 (60–98)	0.63
EF	60 (50–65)	60 (45–65)	0.007
AIx75	17.2 (12.5–28)	21.5 (14.5–33)	<0.001
PWVc-r	7.6 (6.5–10)	8.5 (6.9–11.4)	<0.001
PWVc-f	7.5 (6.3–9.5)	8.3 (7.2–10.7)	<0.001
Oxaliplatin-based (n =44)
SBP	140 (110–160)	130 (105–156)	0.003
DBP	70 (60–90)	70 (60–85)	0.71
EF	60 (55–65)	60 (50–65)	0.072
AIx75	16.4 (12.5–28)	19.5 (15.6–32)	<0.001
PWVc-r	7.4 (6.5–8.6)	8.2 (7–11.4)	<0.001
PWVc-f	7.5 (6.3–8.8)	8.2 (7.2–9.1)	<0.001
Irinotecan-based (n =28)
SBP	145.5 (120–155)	140 (110–156)	0.21
DBP	80 (70–90)	70 (60–98)	0.002
EF	60 (50–65)	60 (55–65)	0.57
AIx75	18.5 (14.5–23)	23.9 (17.2–31.5)	<0.001
PWVc-r	8 (7.4–10)	8.9 (8.1–11)	<0.001
PWVc-f	7.95 (6.5–9.5)	8.6 (8.3–10.7)	<0.001
Capecitabine-based (n =21)
SBP	136 (120–145)	130 (112–150)	0.74
DBP	69 (60–80)	70 (60–85)	0.012
EF	60 (50–65)	60 (45–65)	0.057
AIx75	17.2 (12.5–20)	21.3 (14.5–33)	<0.001
PWVc-r	7.5 (6.9–8.1)	8.5 (6.9–9.8)	<0.001
PWVc-f	7.2 (6.3–8.1)	7.8 (7.5–9)	<0.001

Notes:

Wilcoxon signed-rank test. Values in bold denote significance (P<0.05).

Abbreviations: AIx75, augmentation index (heart rate-corrected); DBP, diastolic blood pressure; EF, ejection fraction; SBP, systolic blood pressure; PWV, pulse wave velocity; PWVc-f, carotid–femoral PWV; PWVc-r, carotid–radial PWV.

Table 6

Multiple regression analysis with SBP, DBP, EF, AIx75, PWVc-f, and PWVc-r pre- and postchemotherapy as dependent variables

Variables	β	SE (β)	P-value
SBP difference (after – before)
GIST vs bowel	3.88	2.98	0.19
Kidney vs bowel	3.31	1.87	0.078
Sex (female)	3.52	1.94	0.071
BMI	0.20	0.13	0.14
SBP at baseline	−0.30	0.06	,0.001
SBP difference (after – before)
GIST vs bowel	1.86	1.89	0.33
Kidney vs bowel	−2.64	1.21	0.030
Sex (female)	−0.41	1.25	0.75
BMI	0.001	0.09	0.99
DBP at baseline	−0.70	0.07	,0.001
EF difference (after – before)
GIST vs bowel	−0.14	0.80	0.87
Kidney vs bowel	−1.19	0.51	0.021
Sex (female)	−0.96	0.53	0.071
BMI	−0.07	0.04	0.071
EF at baseline	−0.21	0.06	0.002
AIx75 difference (after – before)
GIST vs bowel	−3.28	0.72	,0.001
Kidney vs bowel	−2.66	0.49	,0.001
Sex (female)	−0.02	0.49	0.97
BMI	0.01	0.03	0.79
AIx75 at baseline	0.01	0.09	0.92
PWVc-r difference (after – before)
GIST vs bowel	−0.24	0.16	0.14
Kidney vs bowel	−0.19	0.11	0.089
Sex (female)	0.001	0.11	0.99
BMI	0.02	0.01	0.001
PWVc-r at baseline	−0.09	0.08	0.24
PWVc-f difference (after – before)
GIST vs bowel	−0.08	0.13	0.53
Kidney vs bowel	−0.06	0.08	0.44
Sex (female)	0.09	0.08	0.29
BMI	0.01	0.01	0.15
PWVc-f at baseline	−0.40	0.06	,0.001

Note: Values in bold denote significance (P<0.05).

Abbreviations: AIx75, augmentation index (heart rate-corrected); BMI, body-mass index; DBP, diastolic blood pressure; GIST, gastrointestinal stromal tumor; PWV, pulse wave velocity; PWVc-f, carotid–femoral PWV; PWVc-r, carotid–radial PWV; SBP, systolic BP; EF, ejection fraction.

Discussion

The main findings of the present prospective study were as follows. Patients with metastatic colorectal cancer, kidney cancer, and GISTs had worse central hemodynamic measurements postchemotherapy. Differences noted in arterial stiffness indices were independent of BMI and BP, whereas patients with metastatic colorectal cancer exhibited a greater increase in AIx compared to GISTs and kidney cancer. In patients with metastatic colorectal cancer, the subgroup of irinotecan-based chemotherapy had higher PWVc-f values postchemotherapy compared to the oxaliplatin and capecitabine subgroups. In all three types of malignancy, patients with higher baseline SBP, DBP, EF, and PWVc-f values exhibited smaller differences postchemotherapy, while AIx75 baseline levels showed no relation to postchemotherapy levels.

To our knowledge, this is the first prospective study to assess arterial stiffness indices pre- and posttreatment with antiangiogenic-based regimens in three malignancy types. Even though there is a positive trend in improved cancer-related mortality, an emerging increase in CV mortality and morbidity in these patients is also noted.19 Though highly effective in the treatment of solid tumors, new anticancer agents that inhibit the VEGF-signaling pathway raise concerns regarding their CV safety. Unfortunately, cancer and CVD share some common pathways;20,21 therefore, it is difficult to ascertain whether cancer per se or chemotherapy agents are the predominant causes of CV complications seen in these patients.

In our study, all arterial stiffness indices increased significantly postchemotherapy in all three types of cancer, whereas AIx75 showed a greater increase in patients with metastatic bowel cancer compared to patients with kidney and GIST malignancy. The fact that there was a rapid increase in arterial stiffness indices (immediately after six to eight cycles of chemotherapy) suggests a rather acute process (ie, endothelial dysfunction, increase in smooth-muscle tone), rather than a chronic one (ie, atherosclerosis, increased collagen synthesis). This finding is in line with previous studies that investigated mainly the effect of anthracycline chemotherapy on arterial stiffness indices.22,23

Sunitinib and pazopanib were used for the treatment of kidney cancer, whereas imatinib was used for GIST patients. These all are TKIs. Panitumumab is an anti-EGFR inhibitor that was used along with standard chemotherapy for patients with metastatic colorectal cancer. These new targeted therapies that inhibit the VEGF-signaling pathway (vascular pathway inhibitors) are linked to higher BP levels posttreatment. In our study, a significant increase in SBP was noted only in patients with colorectal metastatic cancer. However, a possible induced arterial stiffening process seen in our study could be explained by the fact that vascular pathway inhibitors could cause a reduction in nitric oxide production,24 and increased expression of prohypertensive agents,25 such as endothelin 1, also cause microvascular rarefaction,26 activate the renin–angiotensin system,27 increase oxidative stress,28 and induce the pressure-natriuresis system,29 leading to alterations in the mechanical properties of large vessels and thus arterial stiffening. Despite the complexity of the mechanisms involved, our data suggest a clear burden of arterial stiffness in these patient’s posttreatment, without any other evidence of complementary cardiotoxicity.

In the subgroup of irinotecan-based chemotherapy, along with panitumumab, for metastatic colorectal cancer we noted higher PWVc-f values postchemotherapy compared to capecitabine- and oxaliplatin-based treatments. Irinotecan is a topoisomerase I inhibitor that has been shown to improve survival and quality of life significantly in patients with 5-fluorouracil-resistant disease.30,31 Irinotecan is not associated with cardiotoxicity; however, our data suggest a trend toward higher arterial stiffness indices, which could be a point of further investigation in a larger cohort of patients with metastatic colorectal cancer.

Finally, patients with higher baseline SBP, DBP, and PWV values exhibited smaller differences postchemotherapy, whereas AIx75 was independent of baseline values. Overall, this finding suggests that patients with better baseline central hemodynamics are more prone to an acute effect induced by chemotherapy. Furthermore, AIx is a marker that could potentially be used more objectively for the assessment of arterial stiffening seen in these patients.

The main limitation of the present study is the lack of a control group. However, that would have been unethical and, thus, was not considered an option. The study’s strength derives from its blinded characteristics: physicians assessing arterial stiffness were not aware of the type of cancer or patient-treatment regimens, along with the fact that measurements were performed before and immediately after the termination of treatment.

Conclusion

This prospective study suggests a clear burden in arterial stiffness in patients under chemotherapy for kidney, GISTs, and metastatic colorectal cancer irrespectively of BP and other confounders. AIx is a better index for such patients, whereas patients with lower baseline BP and arterial stiffness exhibited greater changes. Further, larger studies would need to be conducted to allow generalization of the results.