|Year : 2022 | Volume
| Issue : 4 | Page : 268-275
|Outcomes of combined pyloric botulinum toxin injection and balloon dilation in dyspepsia with and without delayed gastric emptying
Neha R Santucci1, Sarah Kemme2, Khalil I El-Chammas1, Maneesh Chidambaram1, Manav Mathur1, Daniel Castillo1, Qin Sun3, Lin Fei3, Ajay Kaul1
1 Gastroenterology, Hepatology and Nutrition, Cincinnati Children's Hospital Medical Center, OH and Department of Pediatrics, University of Cincinnati College of Medicine, Denver, CO, United States of America
2 Gastroenterology, Hepatology and Nutrition, Children's Hospital of Colorado, Denver, CO, United States of America
3 Biostatistics, Cincinnati Children's Hospital Medical Center, Cincinnati, OH, United States of America
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|Date of Submission||11-Sep-2021|
|Date of Acceptance||17-Oct-2021|
|Date of Web Publication||25-Jan-2022|
| Abstract|| |
Background: Pyloric botulinum toxin injection has improved symptoms in children with delayed gastric emptying. We aimed to determine the clinical response to combined endoscopic intra-pyloric botulinum toxin injection and pyloric balloon dilation (IPBT-BD) in patients with dyspepsia.
Methods: Electronic medical records were reviewed to gather demographic data, symptoms, and follow-up on patients with dyspepsia. Cases were defined as those who underwent IPBT-BD in addition to their ongoing management. Controls received pharmacotherapy, behavioral intervention, or dietary management alone. Clinical response was defined as no change, partial, or complete improvement in symptoms within 12 months. Propensity score matching based on age, gender, and symptom duration was used to pair cases and controls.
Results: In total, 79 cases and 83 controls were identified. After propensity matching, 63 patients were included in each group. The mean age for cases was 14.5 ± 3.9y; 62% were females and 98% were Caucasian. Further, 83% of 46 cases and 94% of 49 controls who had scintigraphy scans showed delayed gastric emptying. After matching, 76% of cases showed partial or complete improvement compared with 49% controls within 12 months (P = 0.004). Younger children tended to respond more favorably to the procedure (P = 0.08).
Conclusions: In our propensity-matched analysis, combined IPBT-BD in addition to pharmacotherapy, behavioral, or dietary management clearly showed a benefit over these modalities alone. This favorable response lasted up to 12 months.
Keywords: Delayed gastric emptying, dyspepsia, pediatric, pyloric Botox, pyloric dilation
|How to cite this article:|
Santucci NR, Kemme S, El-Chammas KI, Chidambaram M, Mathur M, Castillo D, Sun Q, Fei L, Kaul A. Outcomes of combined pyloric botulinum toxin injection and balloon dilation in dyspepsia with and without delayed gastric emptying. Saudi J Gastroenterol 2022;28:268-75
|How to cite this URL:|
Santucci NR, Kemme S, El-Chammas KI, Chidambaram M, Mathur M, Castillo D, Sun Q, Fei L, Kaul A. Outcomes of combined pyloric botulinum toxin injection and balloon dilation in dyspepsia with and without delayed gastric emptying. Saudi J Gastroenterol [serial online] 2022 [cited 2022 Aug 10];28:268-75. Available from: https://www.saudijgastro.com/text.asp?2022/28/4/268/336458
| Introduction|| |
Dyspepsia is a common pediatric condition, and symptoms include nausea, emesis, early satiety, bloating, postprandial pain, and weight loss., There is a significant overlap in the symptoms, epidemiology, and pathophysiology of functional dyspepsia and gastroparesis., Recent studies consider them to be a part of a spectrum of gastroduodenal sensorimotor dysfunction.,,A wide array of treatments are employed (pharmacotherapy such as prokinetics, proton pump inhibitors, antidepressants, and eradication of Helicobacter pylori; dietary modifications; and behavioral interventions).Studies have reported suboptimal outcomes or side effects with pharmacotherapy,,,,,and evidence-based data for these treatments in the pediatric population remain lacking.
One potential therapy is the injection of intra-pyloric botulinum toxin (IPBT) injection, which has been shown to improve symptoms in patients with gastroparesis.,,,,,,Botulinum toxin A inhibits the release of acetylcholine into the neuromuscular synaptic cleft, resulting in decreased muscle contractility. This, in turn, is thought to improve pyloric function and improve the symptoms related to delayed gastric emptying.,However, pediatric data is scarce with only a couple of retrospective studies evaluating the efficacy of IPBT in gastroparesis and feeding disorders. These have shown promising results with a 67% response rate in each study., Another treatment targeting pyloric dysfunction is pyloric balloon dilation (BD), which has been performed for anatomic gastric outlet obstruction in adults as well as children secondary to strictures, peptic ulcer disease, post-acid ingestions, and congenital pyloric stenosis.,,,,Pyloric balloon dilation has also improved outcomes in gastroparesis in adults, likely by improving pyloric compliance, but data in pediatrics is limited. There are no studies on the combination of IPBT injection and pyloric BD for pediatric dyspepsia with or without delayed gastric emptying. Therefore, the primary aim of this study was to analyze the long-term response rates of dyspeptic symptoms to the combination of intra-pyloric botulinum toxin injection and pyloric balloon dilation (IPBT-BD) in addition to conventional management, and compare the results with those for children who received conventional management alone. We also sought to assess factors that predicted response to IPBT-BD and conventional treatment. Lastly, we compared the response of combined IPBT-PD from our cohort to two previously published pediatric studies on IPBT to assess the possible added effect of pyloric dilation.
| PATIENTS and Methods|| |
After obtaining approval from the institutional review board, we reviewed the electronic medical records (EMR) and identified all patients aged 0–25 years with ICD 10 codes of dyspepsia, abdominal pain, nausea, vomiting, early satiety, and weight loss without any organic etiology, between January 2012 and May 2019. We excluded patients who had previous IPBT procedures outside our institution and those who did not follow up. We separated them into two groups: those that underwent a single IPBT-BD procedure and those that did not. A standard protocol was used for IPBT-BD. A total of 100 units of botulinum toxin A was injected into the submucosa by using a sclerotherapy needle (Carr-Locke needle, Steris/US Endoscopy, Mentor, OH) and divided into four quadrants of the pylorus (25 units of botulinum toxin A diluted in 0.5mL of NS in each quadrant) [Figure 1]. This was followed by balloon dilation with a controlled radial expansion (CRE) balloon dilator (Boston Scientific, Marlborough, MA @2015) up to 20 mm Hg for 2 min [Figure 2]. The final balloon size for dilation depended on the pyloric diameter measured relative to the size of the scope tip. We performed IPBT injection first, followed by pyloric dilation which allowed the botulinum toxin to dissipate over a larger surface area.
|Figure 1: Intra-pyloric botulinum toxin injection (IPBT). Endoscopic image of botulinum toxin A injection into the pyloric submucosa via a sclerotherapy needle|
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|Figure 2: Pyloric dilation. Endoscopic image of balloon dilation of the pylorus using a controlled radial expansion (CRE) balloon dilator|
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Controls included patients with dyspepsia who received conventional therapy but no IPBT-BD. We collected data on demographics (age, gender, and race), presenting symptoms, symptom duration, scintigraphic gastric emptying scan (GES) results when done, the presence or absence of joint hypermobility syndrome, and psychiatric comorbidities. A delayed GES was defined as <40% emptying at 2 h or <90% at 4 h after a solid meal. A standard meal per divisional radiology protocol was used for GES. Symptom improvement was assessed at the follow-up visit for both groups.
The primary outcome measure was the response to combined IPBT-BD and was classified as follows: 0 = no change, 1 = partial improvement (patient felt better but still had some symptoms), and 2 = complete resolution of symptoms within 12 months, as reported by the patient or caretaker. Secondary outcomes included assessment of response based on follow-up duration and rate of gastric emptying. Factors that predicted response to combined IPBT-BD and to conventional treatment were also identified.
As an exploratory analysis, response rates were compared between this cohort, which included the total number of IPBT-BD patients, and the combined response rates of the two previously published pediatric studies of IPBT., Response rates and 95% confidence intervals were calculated between the number of patients who had a partial or complete response and non-responders and were used to compare with the published response rates.
The IPBT-BD treated (case) patients were matched to control patients according to age (≤5 years and >5 years), gender, and duration of symptoms. This matching was carried out to reduce potential bias in analysis and interpretation due to baseline and disease characterizations because of the non-randomized nature of the study. Propensity score matching was performed, with a propensity score model fit using logistic regression with the group status (case/control) as the response and the above mentioned matching variables as the independent variables. Each case was matched within 0.1 SD of the propensity score. The response at follow-up was compared between the matched case and control groups using the t-test, Chi-Square test, or Fisher's exact test as appropriate. To determine the predictors of response to treatment in each group, a proportional odds regression model with single predictors was used for univariate analysis. Fisher's exact test was used to assess the difference between the response rate of IPBT-BD and the combined response rate from the two previously published pediatric studies of IPBT in the exploratory analysis. Statistical analysis was conducted using R-package “Matching” version 4.9-6 for the matching process on R version 3.6.0. Group comparisons were conducted using SAS 9.4 (SAS Institute Inc., Cary, NC). Continuous variables were summarized as mean, standard deviation, or median as appropriate and indicated in the results.
| Results|| |
A total of 83 controls who underwent conventional management alone and 79 cases with dyspepsia who underwent combined IPBT-BD and conventional management were identified. After a 10% propensity caliper matching for age, sex, and duration of symptoms, 63 patients were included in each group. The demographic and clinical characteristics of the patients are shown in [Table 1]. Only one patient in each group was younger than 5 years of age. Delayed gastric emptying was identified in 83% of 46 cases and 94% of 49 controls who had documented gastric emptying scans. The average duration of symptoms at presentation was 63 days in both groups. Psychiatric comorbidities (anxiety, depression, attention deficit hyperactivity disorder, post-traumatic stress disorder, schizophrenia, and bipolar disorder) were present in 41% of cases and 30% of controls. None of the baseline characteristics (age, gender, race, GES results, symptoms of abdominal pain, nausea, vomiting, early satiety, weight loss, psychiatric comorbidities, present or absence of hypermobility, and duration of symptoms) were statistically different after propensity matching.
|Table 1: Baseline characteristics, before and after matching, in the 12-month follow-up group|
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Before matching, 78% of cases showed partial or complete improvement, for those with follow-up within 12 months, compared to 51% of controls (P = 0.001). After propensity matching, 76% of cases showed partial or complete improvement compared with 49% controls (P = 0.004, [Figure 3]). Specifically, 26% of cases had partial improvement compared with 27% of controls, and 50% of cases had complete improvement with 22% of controls. No adverse events were reported after the procedure.
|Figure 3: Clinical response based on follow-up. Clinical response to combined intra-pyloric botulinum toxin injection and pyloric balloon dilation (IPBT-BD) treatment in matched cases based on follow-up duration|
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We further analyzed patient data for those who were followed up within 3 and 6 months post-intervention [Table 2] and [Figure 3]. Within 3 months, after propensity matching, 78% of cases showed partial or complete improvement compared to 44% of controls (P = 0.006). Within 6 months, 79% of cases showed partial or complete improvement compared to 48% controls (P = 0.0002).
|Table 2: Univariate analysis of clinical response to combined intra-pyloric botulinum toxin injection and pyloric balloon dilation (IPBT-BD) treatment, before and after matching, based on follow-up duration|
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[Table 3] shows the clinical response based on gastric emptying rates in the 12-month follow-up group. Among patients with delayed gastric emptying, those who got IPBT-BD were more likely to show improvement compared to controls (81.6% vs. 50%, P = 0.008). Cases with normal gastric emptying and those with unknown emptying rates also showed improvement compared with controls, although this was not statistically significant.
Predictors of response
[Table 4] summarizes the univariate (logistic) analysis of factors predicting response to IPBT-BD for unmatched cases and conventional treatment for unmatched controls. There was a trend toward younger children responding more favorably to IPBT-BD (P = 0.08). Age did not predict the response for controls. Gender, symptoms, comorbidities, and gastric emptying did not significantly affect response to treatment in either group. However, odds ratio point estimates suggested that cases with nausea and vomiting, and controls with nausea only, responded most favorably to the procedure, although this did not reach statistical significance. Similarly, males, patients with hypermobility, delayed gastric emptying, and those without psychiatric comorbidities responded more favorably to the procedure in both groups, although this did not reach statistical significance.
|Table 4: Univariate analysis of factors predicting response to combined intra-pyloric botulinum toxin injection and pyloric balloon dilation (IPBT-BD) treatment for cases, and conventional treatment for controls, within 12 months of follow-up|
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Comparison of IPBT-BD with historic IPBT response
The response rate of all unmatched patients receiving IPBT-BD who had a partial or complete response 12 months after treatment was78% (95% CI: 69–87%), which is close to the response rate of IPBT-BD (76%) in the control-matched patients. Compared to the pooled response rate of 67% (58%–75%) from Rodriguez et al. and Hirsch et al. (combined total of 87 responders out of 130 total patients), the difference did not reach a statistical significance (P = 0.114) in a Fisher's exact test of 2-by-2 contingency table. There is an obvious trend toward a higher response rate among IPBT-BD patients compared to IPBT only patients in Rodriguez et al. and Hirsch et al. (78% vs. 67%).
| Discussion|| |
This is the first study evaluating the response of IPBT injection combined with pyloric balloon dilation in children or adults with dyspepsia, with and without delayed gastric emptying. In a propensity-matched sample, we have shown a response rate of 76% with combined IPBT injection and pyloric dilation in addition to conventional management compared with the latter alone. Two uncontrolled pediatric retrospective studies have each shown a 67% improvement after IPBT injection alone in children with gastroparesis (n = 45) and in younger children with feeding difficulties including delayed gastric emptying (n = 87). The higher response rate in our sample may be attributed to the inclusion of patients with dyspepsia regardless of gastric emptying status, a propensity-matched control group, a large sample size, and a long duration of follow-up. When comparing our outcome of “any improvement” in the unmatched cohort with the historic studies, we found a 11% higher response, which could be attributed to the effect of pyloric dilation. While open-label studies in adults have demonstrated 55%–100% improvement in symptoms such as nausea and vomiting, ,,,, two small randomized controlled trials (RCT) did not establish the superiority of IPBT over saline injections in gastroparesis in adults. However, these trials included heterogeneous populations with varied etiologies for delayed gastric emptying that may have confounded the results., In adults with gastroparesis, 78% of 33 patients showed overall improvement in symptoms and weight gain after receiving either IPBT (n = 25) or pyloric balloon dilation (n = 8). The majority of patients (79%) in this study had idiopathic delayed gastric emptying.
Among our patients with delayed gastric emptying, those with IPBT-BD had significantly more improvements compared with controls (P = 0.008). Pyloric spasm or fibrosis has been implicated in the pathophysiology of delayed gastric emptying leading to a functional gastric outlet obstruction., Studies in adults with delayed gastric emptying have demonstrated decreased pyloric distensibility and compliance, decreased cross-sectional area and diameter, and increased basal pyloric pressure.,,, Dyschalasia (premature contraction of the pylorus during antral peristalsis) has also been implicated in the pathophysiology of gastroparesis. Based on these studies, the witnessed improvement in symptoms with combined IPBT-BD treatment may be secondary to improved pyloric outflow from increased pyloric distensibility and compliance, as well as improving dyschalasia. It is also hypothesized that altering the pyloric dynamics may cause changes in antral contractility, which in turn improves gastric emptying and associated symptoms.
It has been reported that symptoms do not often correlate with the severity of delayed gastric emptying. Thus, the improvements noted in our cohort with both delayed and normal gastric emptying may be secondary to an altered afferent input from the stomach to the brain. One hypothesis is that IPBT injection may decrease the sensory vagal input from the pylorus to the brain, leading to enhanced symptom response. This is supported by the analgesic effect of botulinum toxin noted in animal studies. Neural evaluation in rat models has shown that botulinum toxin decreases the expression of nociceptors (TRPV1), the secretion of substance P and other pain regulatory neurotransmitters, as well as the peripheral and central sensitization of pain signals in the spinal cord. Direct retrograde axonal transport of botulinum toxin along the branches of nociceptive neurons has also been documented, suggesting its role in treating central neuropathic pain conditions such as post-stroke pain, multiple sclerosis, and complex regional pain syndrome.
We noted a similar rate of symptom relief with the combination of IPBT injection and dilation at all three time-points (3, 6, and 12 months) postintervention. Previous studies have demonstrated that IPBT has an expected symptom relief for about 3 months in children and adults with a few studies in adults showing efficacy up to 4–6 months from treatment.,,,Some of the improvements noted over time in our cohort can be attributed to the natural history of the disease in children. However, given the severity of the symptoms when present, and a lack of well-established, evidence-based treatments, the combined procedure appears to have an advantage over IPBT or BD alone, with a robust and longer-lasting response.
In terms of factors predicting response, we did not find a gender difference between responders versus non-responders, despite mixed data being reported in previous studies.,,Younger age (<50 years) and idiopathic etiology have demonstrated a favorable response to IPBT in adults, which is consistent with our findings. The study by Rodriguez et al. showed that children older than 12 years of age responded better to IPBT. In contrast, our study showed that children less than 14 years of age tended to have a better response to IPBT-PD. Rodriguez et al. used weight-based dosing for IPBT, while we used a fixed dose of 100 units for our entire cohort. As larger doses of Botox as high as 200 units are related to improved responses in adults, , the improvements in our younger patients may be due to a relatively higher dose-for-weight of Botox compared to the prior study. This may also explain our improved outcomes compared to studies in adults. Further elucidation is warranted to evaluate the effect of relative weight-based dosing, especially in combination with pyloric dilation. The type of symptoms and other comorbidities did not significantly affect the response. Though not statistically significant, nausea and vomiting responded more favorably to IPBT-BD. This has been reported in prior studies assessing response to IPBT.,
Our study had a few limitations. The retrospective design of our study may be impacted by the accuracy of EMR documentation. However, a double-blind, placebo-controlled trial is not practical or ethical in children as it has the risk of general anesthesia and would be an invasive procedure in healthy controls. While propensity score-matching employed in our study cannot completely balance known or unknown confounders, it had the advantage of eliminating confounding bias to a degree that closely mimics that of a RCT. Moreover, it was difficult to establish the individual effects of the two procedures as they were combined. However, although not a perfect comparison, we were able to ascertain a higher response of the combined procedure over historic IPBT studies, and this may be attributed to pyloric dilation. A future study could focus on discerning the efficacy of combined pyloric balloon dilation and IPBT compared to IPBT or pyloric dilation alone.We included some patients with delayed emptying of a solid meal at 2h and not 4h exclusively. This is because some patients had their scan done before 4-h scintigraphy was regarded as the gold standard for diagnosing delayed emptying. , However, 2-h abnormal cut-offs have been previously established as >60% retention on scintigraphy, which we used for our study.Our cohort included a heterogeneous population with known and unknown gastric emptying. Thus, performing a subgroup analysis for evaluating improvement in those with normal, delayed, and unknown gastric emptying, impacted the numbers in each of these three subgroups. Therefore, it is likely that a lack of statistically significant improvement of the combined intervention in patients with normal and unknown emptying groups is due to smaller sample sizes, than those with delayed emptying. This highlights the need for future large studies of this intervention in patients with normal gastric emptying. Another limitation was our inability to use Rome 4 criteria for patient selection due to the retrospective nature of the study, as these are not consistently documented in the EMR clinic notes. Similarly, providers included general gastroenterologists as well as neurogastroenterologists.
In conclusion, we demonstrated a significant benefit of combined intra-pyloric botulinum toxin injection and pyloric balloon dilation for children with dyspepsia, especially in those with delayed gastric emptying. The observed response rate of the combined procedure was higher than that reported in previous pediatric studies assessing intra-pyloric botulinum toxin injection alone. Larger scale studies in both children and adults are needed to confirm our findings as this may necessitate a paradigm shift and have a significant impact on the standard of care of patients with dyspepsia.
Jennifer Hardy for providing organized data for collection
CCHMC division of pediatric gastroenterology, hepatology, and nutrition
Financial support and sponsorship
Conflicts of interest
Dr. Kaul has been on the editorial board for the Saudi Journal of Gastroenterology in the past. Other than that, none of the authors have any conflict of interest.
| References|| |
Kovacic K, Elfar W, Rosen JM, Yacob D, Raynor J, Mostamand S, et al
. Update on pediatric gastroparesis: A review of the published literature and recommendations for future research. Neurogastroenterol Motil 2019;32:e13780.
Waseem S, Islam S, Kahn G, Moshiree B, Talley NJ. Spectrum of gastroparesis in children. J Pediatr Gastroenterol Nutr 2012;55:166-72.
Kim BJ, Kuo B. Gastroparesis and functional dyspepsia: A blurring distinction of pathophysiology and treatment. J Neurogastroenterol Motil 2019;25:27-35.
Cangemi DJ, Lacy BE. Gastroparesis and functional dyspepsia: Different diseases or different ends of the spectrum? Curr Opin Gastroenterol 2020;36:509-17.
Franzese A, Borrelli O, Corrado G, Rea P, Di Nardo G, Grandinetti AL, et al
. Domperidone is more effective than cisapride in children with diabetic gastroparesis. Aliment Pharmacol Ther 2002;16:951-7.
Islam S. Gastroparesis in children. Curr Opin Pediatr 2015;27:377-82.
Tillman EM, Smetana KS, Bantu L, Buckley MG. Pharmacologic treatment for pediatric gastroparesis: A review of the literature. J Pediatr Pharmacol Ther 2016;21:120-32.
Romano C, Valenti S, Cardile S, Benninga MA. Functional dyspepsia. J Pediatr Gastroenterol Nutr 2016;63:579-84.
Rodriguez L, Irani K, Jiang H, Goldstein AM. Clinical presentation, response to therapy, and outcome of gastroparesis in children.
J Pediatr Gastroenterol Nutr 2012;55:185-90.
Fuchs HF, Broderick RC, Harnsberger CR, Divo FA, Coker AM, Jacobsen GR, et al
. Intraoperative endoscopic botulinum toxin injection during total esophagectomy prevents the need for pyloromyotomy or dilatation. J Laparoendosc Adv Surg Tech A 2016;26:433-8.
Antonoff MB, Puri V, Meyers BF, Baumgartner K, Bell JM, Broderick S, et al
. Comparison of pyloric intervention strategies at the time of esophagectomy: Is more better? Ann Thorac Surg. 2014;97:1950-7.
Arya S, Markar SR, Karthikesalingam A, Hanna GB. The impact of pyloric drainage on clinical outcome following esophagectomy: A systematic review. Dis Esophagus 2015;28:326-35.
Bagheri R, Fattahi SH, Haghi SZ, Aryana K, Aryanniya A, Akhlaghi S, et al
. Botulinum toxin for prevention of delayed gastric emptying after esophagectomy. Asian Cardiovasc Thorac Ann 2013;21:689-92.
Ezzeddine D, Jit R, Katz N, Gopalswamy N, Bhutani MS. Pyloric injection of botulinum toxin for treatment of diabetic gastroparesis. Gastrointest Endosc 2002;55:920-3.
Miller LS, Szych GA, Kantor SB, Bromer MQ, Knight LC, Maurer AH, et al
. Treatment of idiopathic gastroparesis with injection of botulinum toxin into the pyloric sphincter muscle. Am J Gastroenterol 2002;97:1653-60.
Wellington J, Scott B, Kundu S, Stuart P, Koch KL. Effect of endoscopic pyloric therapies for patients with nausea and vomiting and functional obstructive gastroparesis. Auton Neurosci 2017;202:56-61.
Galligan JJ, Vanner S. Basic and clinical pharmacology of new motility promoting agents. Neurogastroenterol Motil 2005;17:643-53.
Ahuja NK, Clarke JO. Pyloric therapies for gastroparesis. Curr Treat Options Gastroenterol 2017;15:230-40.
Rodriguez L, Rosen R, Manfredi M, Nurko S. Endoscopic intrapyloric injection of botulinum toxin toxin A in the treatment of children with gastroparesis: A retrospective, open-label study. Gastrointest Endosc 2012;75:302-309.
Hirsch S, Nurko S, Mitchell P, Rosen R. Botulinum toxin as a treatment for feeding difficulties in young children. J Pediatr 2020;S0022-3476:30766-6. doi: 10.1016/j.jpeds. 2020.06.063.
Guo F, Huang Y, Zhu W, Wang Z, Cao L, Chen A, et al
. Efficacy and safety of endoscopic balloon dilation for upper gastrointestinal strictures of Crohn's disease. Dig Dis Sci 2016;61:2977-85.
Hamzaoui L, Bouassida M, Ben Mansour I, Medhioub M, Ezzine H, Touinsi H, et al
. Balloon dilatation in patients with gastric outlet obstruction related to peptic ulcer disease. Arab J Gastroenterol 2015;16:121-4.
Bae JS, Kim SH, Shin CI, Joo I, Yoon JH, Lee HJ, et al
. Efficacy of gastric balloon dilatation and/or retrievable stent insertion for pyloric spasms after pylorus-preserving gastrectomy: Retrospective analysis. PLoS One 2015;10:e0144470.
Yokoyama S, Uyama S, Iwagami H, Yamashita Y. Successful combination of endoscopic pyloromyotomy and balloon dilatation for hypertrophic pyloric stenosis in an older child: A novel procedure. Surg Case Rep 2016;2:145.
Andrade M, Sawamura R, Cupo P, Del Ciampo IR, Fernandes MI. Endoscopic treatment of gastric outlet obstruction secondary to accidental acid ingestion in a child. J Pediatr Gastroenterol Nutr 2016;62:90-2.
Gourcerol G, Tissier F, Melchior C, Touchais JY, Huet E, Prevost G, et al
. Impaired fasting pyloric compliance in gastroparesis and the therapeutic response to pyloric dilatation. Aliment Pharmacol Ther 2015;41:360-7.
Lacy BE, Crowell MD, Schettler-Duncan A, Mathis C, Pasricha PJ. The treatment of diabetic gastroparesis with botulinum toxin injection of the pylorus. Diabetes Care 2004;27:2341-7.
Bromer MQ, Friedenberg F, Miller LS, Fisher RS, Swartz K, Parkman HP. Endoscopic pyloric injection of botulinum toxin A for the treatment of refractory gastroparesis. Pharmacol Ther 2005;61:833-9.
Coleski R, Anderson MA, Hasler WL. Factors associated with symptom response to pyloric injection of botulinum toxin in a large series of gastroparesis patients. Dig Dis Sci 2009;54:2634–42.
Arts J, Holvoet L, Caenepeel P, Bisschops R, Sifrim D, Verbeke K, et al
. Clinical trial: A randomized-controlled crossover study of intrapyloric injection of botulinum toxin in gastroparesis. Aliment Pharmacol Ther 2007;26:1251-8.
Friedenberg FK, Palit A, Parkman HP, Hanlon A, Nelson DB. Botulinum toxin A for the treatment of delayed gastric emptying. Am J Gastroenterol 2008;103:416-23.
Pasricha TS, Pasricha PJ. Botulinum toxin injection for treatment of gastroparesis. Gastrointest Endosc Clin N Am 2019;29:97-106.
Mearin F, Camilleri M, Malagelada JR. Pyloric dysfunction in diabetics with recurrent nausea and vomiting. Gastroenterology1986;90:1919-25.
Snape WJ, Lin MS, Agarwal N, Shaw RE. Evaluation of the pylorus with concurrent intraluminal pressure and EndoFLIP in patients with nausea and vomiting. Neurogastroenterol Motil 2016;28:758-64.
Malik Z, Sankineni A, Parkman HP. Assessing pyloric sphincter pathophysiology using EndoFLIP in patients with gastroparesis. Neurogastroenterol Motil 2015;27:524-31.
Ishida S, Miyagawa T, O'Grady G, Cheng LK, Imai Y. Quantification of gastric emptying caused by impaired coordination of pyloric closure with antral contraction: A simulation study. J R Soc Interface 2019;16:20190266.doi: 10.1098/rsif. 2019.0266.
Fisher RS. Gastroduodenal motility disturbances in man. Scand J Gastroenterol Suppl 1985;109:59-68.
Arts J, Van Gool S, Caenepeel P, Verbeke K, Janssens J, Tack J. Influence of intrapyloric botulinum toxin injection on gastric emptying and meal-related symptoms in gastroparesis patients. Aliment Pharmacol Ther 2006;24:661-7.
Park J, Chung ME. Botulinum toxin for central neuropathic pain. Toxins (Basel) 2018;10:224.
Reichenbach ZW, Stanek S, Patel S, Ward SJ, Malik Z, Parkman HP, et al
. Botulinum toxin A improves symptoms of gastroparesis. Dig Dis Sci 2020;65:1396-404.
Chogle A, Saps M. Gastroparesis in children: The benefit of conducting 4-hour scintigraphic gastric-emptying studies. J Pediatr Gastroenterol Nutr2013;56:439-42.
Abell TL, Camilleri M, Donohoe K, Hasler WL, Lin HC, Maurer AH, et al
. Consensus recommendations for gastric emptying scintigraphy: A joint report of the American Neurogastroenterology and Motility Society and the Society of Nuclear Medicine. Am J Gastroenterol 2008;103:753-63.
Tougas G, Eaker EY, Abell TL, Abrahamsson H, Boivin M, Chen J, et al
. Assessment of gastric emptying using a low fat meal: Establishment of international control values. Am J Gastroenterol 2000;95:1456-62.
Dr. Neha R Santucci
Cincinnati Childrenfs Hospital Medical Center, Suite T8.382, Pediatric Gastroenterology, 3333 Burnet Ave, OH - 45229
United States of America
Source of Support: None, Conflict of Interest: None
[Figure 1], [Figure 2], [Figure 3]
[Table 1], [Table 2], [Table 3], [Table 4]
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