Abstract
Introduction
Prevalence rates of chronic abdominal pain (CAP) and breakthrough cancer pain (BTcP) are high in patients with intra-abdominal malignancies. As part of a multimodal approach, CT-guided coeliac plexus blockade (CPB) and CT-guided coeliac plexus neurolysis (CPN) are commonly used pain management strategies. The aim of this study was to evaluate pain outcomes among patients with intra-abdominal malignancies who underwent CPB and/or CPN.
Methods
Patients with intra-abdominal malignancies who underwent CPB and/or CPN for pain control at the general hospital Klagenfurt am Wörthersee from 2010 to 2019 were enrolled.
Results
A total of 84 procedures (24 CPB and 60 CPN) were performed on 52 patients; 62% of these patients had pancreatic cancer. CPN led to significant pain reduction and decreased BTcP intensity. Patients receiving repeated CPN showed higher individual pain reduction. Higher pre-procedural pain intensity was correlated with higher pain reduction. No difference in pain reduction in patients receiving a diagnostic CPB prior to CPN compared to patients without a diagnostic CPB was found. Higher pain reduction after CPN led to longer-lasting pain relief. The time frame from diagnosis to CPN was 472 (± 416) days. Patients experienced a mean duration of pain prior to CPN of 330 (± 53) days. The time frame from diagnosis to CPN was shorter in patients with pancreatic cancer compared to other intra-abdominal malignancies. In 58% of patients pain medication was stable or was reduced after CPN; 16% of patients complained about pain during the procedure; no major complications occurred. There was no correlation between median survival after CPN and pain outcomes.
Conclusions
In patients with intra-abdominal malignancy-related CAP, CPN is a safe and effective procedure which can provide long-lasting significant relief of background pain and BTcP. As part of a multimodal approach, CPN should be considered as an earlier option for pain management in these patients.
Plain Language Summary
In patients with intra-abdominal malignancy-related abdominal pain, CT-guided coeliac plexus neurolysis is a safe and effective procedure. It can provide long-lasting significant relief of background pain and breakthrough cancer pain. As part of a multimodal approach, coeliac plexus neurolysis should be considered as an earlier option for pain management in patients with intractable abdominal cancer pain.
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Why carry out this study? |
In patients with intra-abdominal malignancies, chronic abdominal pain (CAP) has a prevalence up to 50%, and has a huge impact on patients’ quality of life and disability. |
Patients with uncontrolled CAP due to intra-abdominal malignancies develop breakthrough cancer pain (BTcP) in up to 70% of cases. |
The primary objective of this study was to evaluate pain outcomes among patients with intra-abdominal malignancies who underwent CT-guided coeliac plexus neurolysis (CPN). |
What was learned from the study? |
In patients with intra-abdominal malignancy-related abdominal pain, CPN is a safe and effective procedure which can provide long-lasting significant relief of background pain and BTcP. |
As part of a multimodal approach, CPN should be considered as an earlier option for pain management in patients with intractable abdominal cancer pain. |
Introduction
Chronic abdominal pain (CAP) has a prevalence up to 50% in patients with intra-abdominal malignancies, and has a huge impact on patients’ quality of life and disability [3, 24]. Obstruction of hollow viscus, like biliary tract or intestine, or infiltration by cancer masses of the abdominal wall, retroperitoneal, or pelvic structures causes visceral pain due to mixed neuropathic and nociceptive mechanisms [19]. Patients with uncontrolled CAP due to intra-abdominal malignancies develop breakthrough cancer pain (BTcP) in up to 70% of cases [3]. Treatment options as part of a multimodal approach, and standards for the management of cancer-related pain [1], range from medical treatment, typically opioids and centrally targeted pharmacotherapy, as well as interventional pain management procedures [24]. Despite the commonly known side effects of opioids, such as constipation, sedation, dependence, nausea, and respiratory depression or spasm of the sphincter of Oddi, CAP is in many cases refractory to opioid therapy, leading to a vicious circle of dose escalation and unwanted drug side effects [17, 27]. Thus, percutaneous interventional techniques like CT-guided coeliac plexus blockade (CPB) or CT-guided coeliac plexus neurolysis (CPN) are commonly used pain management strategies to decrease pain, increase quality of life, and reduce opioid therapy [24, 30].
The coeliac plexus is the largest autonomic plexus, composed of nerve fibers and ganglia, and because of its radial shape it is known as the solar plexus. The coeliac plexus is located over the anterior and lateral surface of the aorta, next to the origin of the coeliac trunk and the superior mesenteric and renal arteries [8]. It is located in the retroperitoneal fat, posterior to the pancreas and stomach, and separated posteriorly by the diaphragmatic crura [24]. The following nerves join the coeliac plexus: (1) preganglionic sympathetic efferent nerve fibers from the lower thoracic and upper lumbar ganglia; (2) the end of the posterior vagal trunk of the esophageal plexus; (3) the greater and lesser splanchnic nerve [8]. The coeliac plexus comprises two big paired and many smaller ganglia: right and left from the origin of the coeliac trunk from the aorta, a left and right coeliac ganglion is located. More caudally beneath the origin of the superior mesenteric artery, the superior mesenteric ganglion is located. Next to the renal artery, the renal ganglia and the aoriticorenal ganglia are found [8, 24].
Preganglionic parasympathetic efferent fibers from the posterior vagal trunk are also found in the coeliac plexus. These fibers carry autonomic supply to the pancreas, liver, gallbladder, stomach, spleen, kidneys and adrenal glands, small and large bowel, and abdominal blood vessels [2, 24]. Along with splanchnic nerves, also visceral afferent fibers that provide nociceptive stimuli from distal esophagus to the colon pass through the coeliac plexus terminating in the spinal cord [21, 24]. Nociceptive signals then pass through the spinal cord to the thalamus and cortex. As a result of its pain transmission the coeliac plexus is a veritable target for controlling pain from upper abdominal organs [13, 24].
Compared to CPB with injection of corticosteroids and/or long-acting local anesthetics, CPN leads to permanent destruction of the coeliac plexus after injection of phenol or ethanol, due to protein coagulation and necrosis of neural structures [12, 13, 24]. CPB is commonly practiced prior to CPN as a diagnostic blockade, although its clinical significance in clinical routine is questionable [29].
CPN may be accomplished using an anterior para-aortic [13, 22], a bilateral posterior para-aortic [2, 24], a posterior transaortic [13, 15], or a trans-intervertebral disc approach [9, 24]. In all of these approaches, using multidetector computed tomography guidance, patient anatomy, tumor masses, and the needle tip are clearly visible, and hence complication rates are low [13, 20, 24]. The most typical side effect is back pain, which mostly radiates to the shoulder, resulting from neurolysis of sensory nerve fibers [13]. Other side effects are transient pain at the injection site, or diarrhea and hypotension, due to sympathetic blockade [2]. Serious side events, like bleeding complications [26], retroperitoneal hematoma [20], lower extremity paralysis [23], thrombosis of the coeliac trunk or vasospasm of the coeliac artery leading to hepatic, splenic, gastric, or bowel infarction [7, 24] are rare. Complications due to poor needle placement, e.g., kidney injuries, pneumothorax, or neurologic complications due to inadvertent injection of neurolytic agent are scarce when CT guidance is used [13].
The primary objective of this study was to evaluate pain outcomes among patients with intra-abdominal malignancies who underwent CPN. We further analyzed indications, details of the procedure, pre- and post-procedural pain intensities and BTcP, and changes in pain medication after the procedure. Such information should lead to better implementation of CPN in a multimodal approach of pain management and thus improve health care quality in patient with intra-abdominal malignancies.
Methods
Ethics
This retrospective study was approved by the Ethical Committee of Carinthia (S2020-14, 18 April 2020), conducted according to the Helsinki declaration and International Association for the Study of Pain (IASP)’s guidelines for pain research in animals and humans, and authorized by the hospital general management. The requirement for written informed consent was waived by the ethics committee.
Setting
All patients with intra-abdominal malignancies who underwent CPB and/or CPN for pain control at the general hospital Klagenfurt am Wörthersee between January 2010 and January 2019 were identified using our clinical data retrieval system and procedure notes. Each case was reviewed as to abstract baseline demographic data and clinical characteristics, as well as pain- and procedure-related data. Demographic and clinical data were gender, age, primary diagnosis, diagnosis date, and location of the malignancy.
Procedure-related data included details of the procedural approach and injectate, complications, time frame from diagnosis to CPB/CPN, and time frame from start of pain to CPB/CPN. Pain-related data were pre- and post-procedural pain scores (baseline and pain peaks), pre- and post-procedural pain medication, and duration of CPN success. The efficacy of pain control was evaluated before and 1 day after CPB on the basis of the numeric rating scale (11-item NRS; 0, “no pain”–10, “worst pain imaginable”). Patients with incorrect medical records or ambiguous documentation and outcome measures were excluded.
Statistical Analysis
Descriptive statistics were used for the characterization of the observed variables. Appropriate parametric or non-parametric tests were done. Variables were compared by U test (Wilcoxon–Mann–Whitney test) and Kruskal–Wallis test, and by t test and one-factor analysis of variance (ANOVA) in case of normally distributed data. Deviation from zero was investigated by the signed rank test, and by the one-sample t test in case of normally distributed data. Significance of trends was tested by the Jonckheere test. The Kolmogorov–Smirnov test was used for proving normality. Spearman rank correlation coefficient and Pearson correlation coefficient were calculated to examine association between variables. Associations in cross-tables were investigated by chi-square test, and in case of 2 × 2 tables also by exact Fisher test. Significance was defined as a p value less than 0.05; p values are reported to a maximum of three decimal places. Differences in median survival were investigated using the Kaplan–Meier method and compared using a log-rank test. Cox proportional hazard model was used to examine association between variables. For all calculations the statistical package R version 4.0.3 and Hewlett-Packard RPL version 2.15 were used.
Diagnostic CPB and CPN
One physician, who is an expert in this field with 25 years of experience in this technique, performed all CPB and CPN using an anterior approach [13, 24] according to a standardized protocol and technique. No premedication and no sedation during the procedure was given to prevent potential hypotensive events. Patients were positioned in a supine position and local infiltration with 2% lignocaine was used. A needle (Sterican® G23 × 3 1/8″; Ø 0.60 × 80 mm, B. Braun Austria Ges.m.b.H.) was inserted through the anterior abdominal wall into the retropancreatic space which correspondents to the retroperitoneal space [25] and the needle tip was placed anterior to the aorta and the diaphragmatic crura between the superior mesenteric artery and the roots of the coeliac plexus [13]. After confirmation of the needle tip with nonionic contrast medium (Jopamidol/Jopamiro®), 10 ml of bupivacain 0.25% (Bucain® 0.25%) in CPB and 10 ml of ethanol 95% in CPN were injected into the antecrural space.
Results
Demographic Data
Thirty-six percent of patients were female, and 64% were male. The mean age was 65 years, with a range from 24 to 88 years with normal distribution. Baseline demographic and main results are shown in Table 1.
CPB and CPN
In summary, 84 procedures (24 CPB and 60 CPN) were performed on 52 individual patients. Five patients (9%) had a single diagnostic CPB and 19 patients (36.5%) had diagnostic CPB prior to CPN. Thirty-five patients (64%) had one CPN, 11 patients (20%) had two CPN, and 1 patient (2%) had 3 CPN.
Diagnosis
Table 1 shows the primary malignancy of patients who underwent the procedure. All patients were diagnosed with intra-abdominal malignancies and 62% had pancreatic cancer.
Pain Intensity
Before the first CPN, the mean pain intensity (11-item NRS; 0, “no pain”–10, “worst pain imaginable”) was 5.1 (± 1.9), with a statistically significant (p < 0.01) pain reduction after the first CPN (2.4 ± 2.0) (see Fig. 1).
Before the second CPN, the mean pain intensity was 5.5 (± 1.3), with a statistically significant (p < 0.01) pain reduction after the procedure (2.0 ± 1.0) (see Fig. 2).
We found no statistically significant difference (p = 0.2) in mean pain reduction after the first and second CPN, but a statistically significant (p = 0.025) correlation of pain reduction and number of CPN was shown. Furthermore, a higher pre-procedural pain intensity was highly significant (p < 0.01) correlated with a higher pain reduction after blockade. There was no statistically significant difference (p = 0.43) in pain reduction in patients receiving a diagnostic CPB prior to first and second CPN compared to patients without a diagnostic CPB.
There was no difference (p = 0.36) in pain reduction after CPN depending on the primary diagnosis.
BTcP
Before CPN the intensity of BTcP was 7.8 (± 1.1) with a statistically significant (p < 0.01) reduction of intensity after the CPN (4.8 ± 3.0) (see Fig. 3).
There was no difference of reduction of BTcP depending on the number of blockades, pain intensity prior to procedure, or diagnosis.
Duration of Pain Reduction
The mean duration of pain reduction after the first CPN was 78 (± 96) days, and 120 (± 109) days after the second CPN. The median difference (88 vs. 53) of the duration of pain reduction after the first and second CPN was nearly statistically significant (p = 0.101).
A significant (p = 0.048) correlation of pain reduction and duration of pain reduction was found: higher pain reduction after CPN leads to longer-lasting pain reduction.
Patients with pancreatic cancer showed a slightly (p = 0.081) longer reduction of pain intensity compared to patients with other intra-abdominal malignancies. Patients with pancreatic cancer did not receive more CPN compared with other intra-abdominal malignancies.
Time Frame
The time frame from diagnosis to CPN was 472 (± 416) days, and patients experienced a mean duration of pain prior to CPN of 330 (± 53) days. It has been shown that the time frame from diagnosis to CPN was significantly (p < 0.01) shorter in patients with pancreatic cancer compared to other intra-abdominal malignancies. The mean time frame from diagnosis to CPN in patients with pancreatic cancer was 175 (± 175) days.
Medication
Patients were divided into three groups depending on their medication after CPN: group 1, increase of pain medication; group 2, decrease of pain medication; group 3, no change in pain medication.
In 58% of patients pain medication was stable or was reduced after CPN. Group 1 showed significant higher (p = 0.038) post-procedural pain scores compared to groups 2 and 3.
There was no correlation between change in pain medication and number of CPN, reduction of pain intensity, and primary diagnosis, respectively.
Complications
Sixteen percent of patients complained about pain during the procedure. No major complications occurred in patients who underwent CPN.
Survival
In our study population, the median survival from the date of diagnosis was 342 days (95% CI 233–452). The median survival from the date of first CPN was 64 days (95% CI 57–71) and from the date of second CPN was 40 days (95% CI, n.a.) (see Table 1). Kaplan–Meier curves for the survival of patients with pancreatic cancer and those with other cancers are illustrated in Fig. 4. The median survival was significantly lower (p < 0.01) for patients with pancreatic cancer compared to combined other cancer entities. There was no correlation between median survival after CPN and respectively pain reduction after first and second CPN, reduction of BTcP, change in pain medication, time frame from diagnosis to CPN, or duration of pain reduction after first or second CPN.
Discussion
This present study describes pain outcomes among patients with intra-abdominal malignancies who underwent CPN. Despite multimodal pain management strategies in these patients, CAP and BTcP are still common and have a major impact on the patient’s disability and quality of life [3, 17, 24]. In this context, CPN is a palliative intervention with the aim to reduce intractable pain and narcotic requirements [4].
In an earlier evaluation of all in-patients in the general hospital of Klagenfurt am Wörthersee, a mean overall current pain intensity at rest of 1.9 (± 2.5) (11-item NRS) was found [11]. In the present setting, the mean pain intensity was 5.1 (± 1.9) before first CPN and 5.5 (± 1.3) before second CPN with BTcP episodes of 7.8 (± 1.1). Most of these patients were diagnosed with pancreatic cancer. Not only does this cancer entity have high mortality rates and poor prognosis [14] but the predominant symptom is abdominal discomfort and pain at the time of diagnosis [28]. Adequate pain control is crucial given that high background pain intensity and episodes of BTcP negatively affect the patient’s mobilization, mood, and sleep [11] and that many patients with pancreatic cancer or other intra-abdominal malignancies have advanced or inoperable disease at the time of diagnosis [14, 28].
After the first and second CPN we showed major pain relief of current pain, which was independent of the intra-abdominal malignancy. This supports previous literature that showed CPN as an effective procedure for the management of CAP [4, 5, 24]. Moreover, a reduction was found in the intensity of BTcP, independent of the number of procedures or pain intensity prior to the procedure. Interestingly, patients receiving two CPN showed higher individual pain reduction. This stands in contrast to McGreevy et al. [18], who showed that repeated coeliac plexus neurolysis (rCPN) does not lead to better pain relief as the initial CPN.
One factor that was strongly associated with good analgesia after CPN was high pre-procedural pain intensity. Higher pre-procedural pain intensities led to higher pain reduction after the intervention, which stands in contrast to earlier studies [6, 28] showing that a low daily opioid dose and good performance status before CPN was clearly associated with good CPN outcome. The authors concluded that higher opioid doses could reflect poorly controlled pain associated with a more significant tumor burden and recommended CPN as an early option for pain management before opioid dose escalation [6, 28].
No difference was found in pain reduction, side effects, or complications in patients receiving a diagnostic block prior to the first or second CPN compared to patients without a diagnostic block. These results underline the results of Yuen et al. [29], who stated that the clinical significance of CPB is questionable and that its routine use is not warranted before CPN. Ischia et al. [10] showed that a CPB may be false positive for different reasons: a placebo effect, differences in local spread of neurolytic agents and local anesthetics, systemic absorption of the anesthetic. Moreover, a prior CPB may lead to higher procedure-related risks, higher health care costs, or possible false negative results [10, 29].
It has been shown that CPN leads to long-lasting pain control in up to 90% of patients with different intra-abdominal malignancies, particularly in patients with pancreatic cancer [5]. The results of our study support this finding, as the mean duration of pain reduction after the first CPN was 78 (± 96) days, and 120 (± 109) days after the second CPN, and patients with pancreatic cancer showed a trend to longer-lasting pain reduction compared to other intra-abdominal malignancies. Interestingly, higher pain reduction after CPN led to longer-lasting pain control.
It has also been stated that successful CPN reduces analgesic consumption and hence reduces the incidence of unwanted drug side effects [13]. In our survey, 58% of our patients’ pain medication was stable or reduced after successful CPN. These patients also showed significantly lower pain scores compared to patients with the necessity to increase analgesic consumption after the procedure.
Unfortunately, pain medication had to be increased in 42% of our patients. This shows the importance of timing of CPN: patients with poor pre-procedural performance status are more likely to show higher levels of pain [16], and patients with advanced cancer may show multisite mixed pain patterns [28], which may lead to poor analgesic outcomes. Approximately 1 year after onset of pain, patients with intra-abdominal malignancies received CPN. Surprisingly, patients with diagnosed pancreatic cancer wait half as long for this procedure. Taking into account that it has been shown that CPN is a safe and effective procedure, our results suggest that CPN should be considered as an earlier option for pain management in these patients.
Yoon et al. [28] showed that good performance status is an independent predictor for good analgesic efficacy following CPN in patients with pancreatic cancer and that patients with good analgesia after CPN tended to have shorter pain duration before the procedure. Furthermore, they found that the median survival time after CPN for patients with good analgesia from CPN was significantly longer than that of patients with poor pain relief. They also showed that patients with poor analgesia after CPN already had an advanced stage of cancer and poor performance status. In this current study, the median survival time after CPN was not associated with pain reduction after first and second CPN, reduction of BTcP, change in pain medication after CPN, time frame from diagnosis to CPN, or duration of pain reduction after first or second CPN, neither in patients with pancreatic cancer nor in patients with other cancer entities. Even though this result stands in contrast to Yoon et al. [28], we acknowledge that survival outcomes do seem to be affected more by the patients’ conditions as well as the progression of the disease, and less so than the analgesic effect of CPN. Nevertheless, we strongly recommend an early CPN in selected patients.
There are several important limitations in our study that deserve mention. One is that it used a retrospective design in a single center. Therefore, we could not completely evaluate detailed pain-related outcomes after discharge. In addition, given the poor life expectancy of most of our patients, long-term follow-up was not possible. As already described in earlier studies [28], this survey used a real-world clinical practice model in which different pain physicians planned the treatment approach for managing cancer pain. So, the decision for performing a CPN or other treatment options could have been influenced by their own preconceptions, and may bias our study population. Despite these limitations, we feel that our large study population, our standardized procedure, and the fact that the technique was performed by one pain physician only allow us to make valid conclusions.
Conclusions
CPN is a safe and effective procedure in patients with intra-abdominal malignancy-related abdominal pain and can provide long-lasting significant relief of background pain and BTcP. As part of a multimodal approach, CPN should be considered as an earlier option for pain management in patients with intractable abdominal cancer pain.
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Acknowledgements
Funding
No funding or sponsorship was received for this study or publication of this article. The journal’s Rapid Service Fee was funded by the authors.
Authorship
All named authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship for this article, take responsibility for the integrity of the work as a whole, and have given their approval for this version to be published.
Author Contributions
Stefan Neuwersch-Sommeregger: substantial contribution to conception and design, interpretation of data, drafting, final approval of the final version. Markus Köstenberger: substantial contribution to conception and design, interpretation of data, drafting, final approval of the final version. Haro Stettner: statistical analysis, interpretation of data. Wolfgang Pipam: statistical analysis, interpretation of data. Christian Breschan: revising the article and interpretation of data. Georg Feigl: interpretation of data, drafting, and revising the article. Rudolf Likar: substantial contribution to conception and design, interpretation of data, drafting, final approval of the final version. Markus Egger: substantial contribution to conception and design, interpretation of data, drafting, final approval of the final version.
Disclosures
Stefan Neuwersch-Sommeregger, Markus Köstenberger, Haro Stettner, Wofgang Pipam, Christian Breschan, Georg Feigl, Rudolf Likar, and Markus Egger confirm that no conflicts of interest exist.
Compliance with Ethics Guidelines
This retrospective study was approved by the Ethical Committee of Carinthia (S2020-14, 18 April 2020), conducted according to the Helsinki declaration and IASP’s guidelines for pain research in animals and humans, and authorized by the hospital general management. The requirement for written informed consent was waived by the ethics committee.
Data Availability
The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.
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Neuwersch-Sommeregger, S., Köstenberger, M., Stettner, H. et al. CT-Guided Coeliac Plexus Neurolysis in Patients with Intra-Abdominal Malignancy: A Retrospective Evaluation of 52 Palliative In-Patients. Pain Ther 10, 1593–1603 (2021). https://doi.org/10.1007/s40122-021-00317-1
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DOI: https://doi.org/10.1007/s40122-021-00317-1