Submitted Successfully!
To reward your contribution, here is a gift for you: A free trial for our video production service.
Thank you for your contribution! You can also upload a video entry or images related to this topic.
Version Summary Created by Modification Content Size Created at Operation
1 format correct
Manuel Barberio
 + 1734 word(s) 1734 2020-10-22 10:35:49 |
2 format correct
Bruce Ren
 Meta information modification 1734 2020-10-23 03:50:22 |

Video Upload Options

Do you have a full video?
Send video materials Upload full video

Confirm

Are you sure to Delete?
Yes No
Cite
If you have any further questions, please contact Encyclopedia Editorial Office.
Barberio, M.; Felli, E.; Pop, R.; Pizzicannella, M.; Geny, B.; Lindner, V.; Baiocchini, A.; Jansen-Winkeln, B.; Moulla, Y.; Agnus, V.; et al. Novel hybrid IGP before Esophagectomy. Encyclopedia. Available online: https://encyclopedia.pub/entry/2759 (accessed on 16 April 2024).
Barberio M, Felli E, Pop R, Pizzicannella M, Geny B, Lindner V, et al. Novel hybrid IGP before Esophagectomy. Encyclopedia. Available at: https://encyclopedia.pub/entry/2759. Accessed April 16, 2024.
Barberio, Manuel, Eric Felli, Raoul Pop, Margherita Pizzicannella, Bernard Geny, Veronique Lindner, Andrea Baiocchini, Boris Jansen-Winkeln, Yusef Moulla, Vincent Agnus, et al. "Novel hybrid IGP before Esophagectomy" Encyclopedia, https://encyclopedia.pub/entry/2759 (accessed April 16, 2024).
Barberio, M., Felli, E., Pop, R., Pizzicannella, M., Geny, B., Lindner, V., Baiocchini, A., Jansen-Winkeln, B., Moulla, Y., Agnus, V., Marescaux, J., Gockel, I., & Diana, M. (2020, October 22). Novel hybrid IGP before Esophagectomy. In Encyclopedia. https://encyclopedia.pub/entry/2759
Barberio, Manuel, et al. "Novel hybrid IGP before Esophagectomy." Encyclopedia. Web. 22 October, 2020.
Novel hybrid IGP before Esophagectomy
Edit
This entry is adapted from the peer-reviewed paper 10.3390/cancers12102977

Esophagectomy has a high rate of anastomotic complications thought to be caused by poor perfusion of the gastric graft, which is used to restore the continuity of the gastrointestinal tract. Ischemic gastric preconditioning (IGP), performed by partially destroying preoperatively the gastric vessels either by means of interventional radiology or surgically, might improve the gastric conduit perfusion. Both approaches have downsides. The timing, extent and mechanism of IGP remain unclear. A novel hybrid IGP method combining the advantages of the endovascular and surgical approach was introduced in this study. IGP improves unequivocally the mucosal and serosal blood-flow at the gastric conduit fundus by triggering new vessels formation. The proposed timing and extent of IGP were efficacious and might be easily applied to humans. This novel minimally invasive IGP technique might reduce the anastomotic leak rate of patients undergoing esophagectomy, thus improving their overall oncological outcome.

esophageal cancer esophageal resection Ivor-Lewis procedure optical imaging anastomotic leak hyperspectral imaging fluorescence imaging confocal laser endomicroscopy ischemic preconditioning

1. Introduction

Esophageal cancer is ranked seventh worldwide among all cancers, in terms of incidence (572,000 new cases) and ranked sixth for mortality rates (509,000 deaths) [1]. The treatment is multidisciplinary and surgery plays a central role in the therapeutic strategy [2]. Esophageal resection is a major surgical high-risk procedure with considerable complication rates [3], which may negatively impact the overall oncological outcome as well as the quality of life of patients [4][5]. In particular, the incidence of anastomotic leak (AL) is relevantly higher, when compared to other gastrointestinal anastomoses [6]. The etiology of AL is multifactorial. Some risk factors to develop AL are not modifiable and include preexisting relevant comorbidities [7] (e.g., hypertension, renal failure, congestive heart failure, smoking), and probably most importantly the presence of substantial atherosclerosis [8]. Appropriate blood supply at the gastric conduit fundus (GCF) is one of the key factors to promote anastomotic healing and to reduce the risk of AL [9]. The formation of the gastric conduit implies the tubulation of the stomach, the sudden disruption of a large part of its vascular supply, with the conduit fed by the gastroepiploic arcade only (and smaller branches of the right gastric artery, if preserved). This results in relative ischemia, especially at the apical section of the gastric graft, the former fundus, which will constitute the proximal portion of the esophagogastric anastomosis.

Ischemic gastric preconditioning (IGP) has been previously proposed to improve the relative ischemia of the GCF by enhancing local microcirculation [10][11][12]. IGP consists in the partial devascularization of the stomach, using either an endovascular or a laparoscopic approach, several days or weeks before gastric pull-up and esophagogastric anastomosis completion. Although IGP has shown promising results in experimental settings and is a recognized safe procedure, it has failed to show a significant AL rate decrease to justify its implementation in the clinical routine [10][11][12][13][14]. This probably results from the large heterogeneity in terms of adopted IGP protocols and importantly from a too short delay between IGP and esophagectomy.

As clinical intraoperative appraisal of the gastrointestinal tract blood flow is not accurate [15], several technologies have been explored to evaluate gastrointestinal perfusion during esophagectomy [16][17][18]. Fluorescence angiography (FA), a technique requiring a near-infrared (NIR) camera and the injection of a fluorophore, has become increasingly available and has shown promising results. However, FA is currently lacking a standardized quantification method. Florescence-based enhanced reality (FLER), allows for precise quantitative fluorescence angiography in the digestive tract, and it has previously shown its accuracy during experimental gastrointestinal procedures [19][20]. Hyperspectral imaging (HSI) is another intraoperative optical imaging modality, which allows for contrast-free tissue oxygen quantification. HSI has proven accurate in assessing intestinal perfusion intraoperatively [21][22]. However, both FLER and HSI allow blood flow estimation exclusively at the serosal side. Confocal laser endomicroscopy (CLE) is a high-resolution microscopic imaging modality, which has been successfully used to quantify mucosal microcirculation within the digestive tract [23][24][25][26].

2. Discussion

AL has a multifactorial etiology. However, anastomotic site perfusion is a controllable risk factor of leakage [16][17][18]. It has been previously demonstrated in a number of experimental studies [27][28][29][30] that IGP improves GCF perfusion, provided that a minimum delay of 2 to 3 weeks is observed between IGP and gastric conduit formation. Similarly, the results of the present study unequivocally demonstrate that IGP, applied 3 weeks prior to gastric tubulation, improves mucosal and serosal perfusion at the GCF, assessed by means of quantitative optical imaging technologies. These findings are supported by LCL levels, which are a robust surrogate of perfusion in the porcine digestive tract [31]. Additionally, the presence of incremented vessels and inflammatory cells (eosinophils) in both IGP groups represents an indirect sign of neovascularization [32][33]. The choice to count eosinophiles has multiple reasons. In fact, these cells have been characterized as proangiogenic actors in the last two decades [33]. In particular, they take part of the innate cells group that contribute to the production of important mediators of the angiogenic/lymphangiogenic factors [34]. Additionally, eosinophils are easily visible under light microscope even at low resolution and low magnification, given their unique bilobate shape with a cytoplasm characterized by a large number of granules confering a specific reddish coloration to these cells in the hematoxylin and eosin staining. Thus, compared with other immune cells, eosinophils are the main visible actors playing a major role in angiogenesis. The histological findings of increased vessel density were confirmed by the immunohistochemical staining (overexpression of the reliable mature vessel indicators, such as CD31 and caldesmone within the specimens of both IGP groups [35]). Those findings, together with the increased eosinophils’ count, demonstrate new vessel formation over a 21 days period, triggered by the hybrid ischemic preconditioning.

Despite promising results in experimental studies, when translated to humans, IGP has failed to exhibit a clear advantage in terms of AL reduction following esophageal resection. Yet, the clinical trials using IGP are highly heterogeneous in terms of technique (angiographic embolization [36][37][38] or laparoscopic vessels ligation [39][40][41][42]) and number of vessels involved, and they are mostly of retrospective nature. Importantly, the delay between preconditioning and esophagectomy is largely variable in those studies. This heterogeneity could account for the apparent clinical inefficacy of ischemic preconditioning. However, the severity of the anastomotic complications in patients who receive IGP seems to be milder as compared to patients who undergo esophagectomy without preconditioning.

Authors using an endovascular approach reported better results in terms of increased GCF perfusion [36] or even AL reduction [38] as compared to the ones using laparoscopy. In fact, the largest patient series using laparoscopic IGP describe shorter time intervals than 2 weeks [43]. This results from the potential adhesion formation that laparoscopic vessel ligation or complete gastrolysis might induce [44]. In this respect, performing esophagectomy 4 to 5 days after laparoscopic IGP represents a convenient strategy in order to reduce the risk of finding firm adhesions intraoperatively, hence potentially increasing the esophagectomy operative time and difficulty degree. On the other hand, when performing endovascular IGP, it was possible to mostly maintain a two-week delay with esophagectomy. Additionally, it has been observed in a clinical series that a short delay between IGP and surgery (< 15 days) might have deleterious effects on GCF blood supply, whereas a 2-week interval seemed to be protective against AL [42].

Interestingly, another group [16] found an increment in terms of mucosal oxygen saturation, measured using an endoluminal spectroscopic probe, in patients undergoing esophagectomy 4 to 5 days after laparoscopic IGP. Conversely, the same group [41] found no neoangiogenesis, assessed through VEGF (vascular-endothelial-growth-factor) increase, in the gastric fundus of patients who underwent laparoscopic IGP 4 to 5 days prior to esophagectomy. These findings suggest that there is a transitory compensating mechanism against the relative ischemia generated with IGP, involving a provisional redistribution of microcirculation, possibly via shunts opening, in its initial phases (4–5 days). This compensation eventually consolidates through the progressive formation of new capillaries, which are detectable after 2 to 3 weeks, as confirmed by our study.

The radiological IGP approach is less invasive than laparoscopy and is suitable to be performed several weeks prior to esophagectomy. However, the SGAs, which, together with the LGA, participate consistently in the gastric fundus vascular supply [45], are technically difficult to embolize. In fact, most authors performing angiographic IGP describe a direct embolization of the splenic artery, potentially increasing spleen infarction risk [46]. As a result, we introduced a hybrid laparo-angiographic technique, in which IGP is achieved mainly angiographically, while the SGAs are divided laparoscopically, resulting in a minimization of the surgical manipulation. Indeed, the lack of adhesions at T21 laparotomy seems to support our hypothesis, which needs to be verified in humans.

No substantial difference was encountered in terms of perfusion between max- and min-IGP groups. An explanation might be that the majority of the gastric fundus blood flow is supplied by the SGAs and the LGA in humans [45]. This might be true in pigs as well, as a result the role of the LGEA (additionally embolized in max IGP) in terms of fundic perfusion could be minimal. However, the small sample size of our study could limit the significance of the results, therefore further studies with larger numbers are required in order to precisely understand the required extent of IGP. Nevertheless, min-IGP showed a higher safety profile than max-IGP, suggesting a better suitability for a potential clinical translation. Hybrid IGP might be an option for patients presenting resectable esophageal cancer and it could be performed in the context of the staging phase, which usually takes place at least 3 weeks before esophagectomy.

The merits of our study lie in the innovative approach, the survival design, and the robust methodology, implementing cutting-edge optical imaging technologies, allowing to quantify real-time perfusion.

The main downside is represented by limiting the surgical procedure to gastric conduit formation without esophagectomy and appraisal of the AL rate. This choice was taken considering that designing AL rate as primary endpoint, much larger groups would have been required to obtain a sufficiently powered study. Additionally, during preparation experiments preceding this work, we noticed a high intraoperative mortality in animals undergoing esophagectomy, possibly due to bradycardia triggered by extreme vasovagal sensitivity. This might justify the fact that, to our knowledge, no survival experiments have been published using a porcine esophagectomy model.

3. Conclusions

In conclusion, hybrid IGP improves mucosal and serosal blood flow of the future anastomotic region on the gastric conduit fundus. Our work suggests that the sole embolization of the LGA associated to the laparoscopic division of the SGAs (min IGP) would elicit an efficacious ischemic preconditioning effect improving gastric fundus perfusion. Those promising results need to be interpreted with caution and a clinical translation is necessary to demonstrate the validity of our protocol in humans undergoing esophageal resection.

References

  1. Bray, F.; Ferlay, J.; Soerjomataram, I.; Siegel, R.L.; Torre, L.A.; Jemal, A. Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J. Clin. 2018, 68, 394–424.
  2. Van Hagen, P.; Hulshof, M.; Van Lanschot, J.; Steyerberg, E.; Henegouwen, M.V.B.; Wijnhoven, B.; Richel, D.; Nieuwenhuijzen, G.; Hospers, G.; Bonenkamp, J. et al. Preoperative chemoradiotherapy for esophageal or junctional cancer. N. Engl. J. Med. 2012, 366, 2074–2084.
  3. Low, D.E.; Kuppusamy, M.K.; Alderson, D.; Cecconello, I.; Chang, A.C.; Darling, G.; Davies, A.; D’Journo, X.B.; Gisbertz, S.S.; Griffin, S.M. et al. Benchmarking complications associated with esophagectomy. Ann. Surg. 2019, 269, 291–298.
  4. Booka, E.; Takeuchi, H.; Suda, K.; Fukuda, K.; Nakamura, R.; Wada, N.; Kawakubo, H.; Kitagawa, Y. Meta‐analysis of the impact of postoperative complications on survival after oesophagectomy for cancer. BJS Open 2018, 2, 276–284.
  5. Markar, S.; Gronnier, C.; Duhamel, A.; Mabrut, J.-Y.; Bail, J.-P.; Carrere, N.; Lefevre, J.H.; Brigand, C.; Vaillant, J.-C.; Adham, M. et al. The impact of severe anastomotic leak on long-term survival and cancer recurrence after surgical resection for esophageal malignancy. Ann. Surg. 2015, 262, 972–980.
  6. Morse, B.C.; Simpson, J.P.; Jones, Y.R.; Johnson, B.L.; Knott, B.M.; Kotrady, J.A. Determination of independent predictive factors for anastomotic leak: Analysis of 682 intestinal anastomoses. Am. J. Surg. 2013, 206, 950–956.
  7. Kassis, E.S.; Kosinski, A.S.; Ross, P., Jr.; Koppes, K.E.; Donahue, J.M.; Daniel, V.C. Predictors of anastomotic leak after esophagectomy: An analysis of the society of thoracic surgeons general thoracic database. Ann. Thorac. Surg. 2013, 96, 1919–1926.
  8. Van Rossum, P.S.; Haverkamp, L.; Verkooijen, H.M.; van Leeuwen, M.S.; van Hillegersberg, R.; Ruurda, J.P. Calcification of arteries supplying the gastric tube: A new risk factor for anastomotic leakage after esophageal surgery. Radiology 2015, 274, 124–132.
  9. Zehetner, J.; DeMeester, S.R.; Alicuben, E.T.; Oh, D.S.; Lipham, J.C.; Hagen, J.A.; DeMeester, T.R. Intraoperative assessment of perfusion of the gastric graft and correlation with anastomotic leaks after esophagectomy. Ann. Surg. 2015, 262, 74.
  10. Kechagias, A.; van Rossum, P.S.; Ruurda, J.P.; van Hillegersberg, R. Ischemic conditioning of the stomach in the prevention of esophagogastric anastomotic leakage after esophagectomy. Ann. Thorac. Surg. 2016, 101, 1614–1623.
  11. Heger, P.; Blank, S.; Diener, M.K.; Ulrich, A.; Schmidt, T.; Buechler, M.W.; Mihaljevic, A.L. Gastric preconditioning in advance of esophageal resection-systematic review and meta-analysis. J. Gastrointest. Surg. 2017, 21, 1523–1532.
  12. Mingol-Navarro, F.; Ballester-Pla, N.; Jimenez-Rosellon, R. Ischaemic conditioning of the stomach previous to esophageal surgery. J. Thorac. Dis. 2019, 11, S663.
  13. Markar, S.R.; Karthikesalingam, A.; Thrumurthy, S.; Low, D.E. Volume-outcome relationship in surgery for esophageal malignancy: Systematic review and meta-analysis 2000–2011. J. Gastrointest. Surg. 2012, 16, 1055–1063.
  14. Siegal, S.R.; Parmar, A.D.; Haisley, K.R.; Tieu, B.H.; Schipper, P.H.; Hunter, J.G.; Dolan, J.P. Gastric Ischemic Conditioning Prior to Esophagectomy Is Associated with Decreased Stricture Rate and Overall Anastomotic Complications. J. Gastrointest. Surg. 2018, 22, 1501–1507.
  15. Karliczek, A.; Harlaar, N.; Zeebregts, C.; Wiggers, T.; Baas, P.; Van Dam, G. Surgeons lack predictive accuracy for anastomotic leakage in gastrointestinal surgery. Int. J. Colorectal Dis. 2009, 24, 569–576.
  16. Bludau, M.; Hölscher, A.H.; Vallböhmer, D.; Gutschow, C.; Schröder, W. Ischemic conditioning of the gastric conduit prior to esophagectomy improves mucosal oxygen saturation. Ann. Thorac. Surg. 2010, 90, 1121–1126.
  17. Köhler, H.; Jansen-Winkeln, B.; Maktabi, M.; Barberio, M.; Takoh, J.; Holfert, N.; Moulla, Y.; Niebisch, S.; Diana, M.; Neumuth, T. et al. Evaluation of hyperspectral imaging (HSI) for the measurement of ischemic conditioning effects of the gastric conduit during esophagectomy. Surg. Endosc. 2019, 33, 3775–3782.
  18. Veeramootoo, D.; Shore, A.C.; Wajed, S.A. Randomized controlled trial of laparoscopic gastric ischemic conditioning prior to minimally invasive esophagectomy, the LOGIC trial. Surg. Endosc. 2012, 26, 1822–1829.
  19. Diana, M.; Agnus, V.; Halvax, P.; Liu, Y.Y.; Dallemagne, B.; Schlagowski, A.I.; Geny, B.; Diemunsch, P.; Lindner, V.; Marescaux, J. et al. Intraoperative fluorescence‐based enhanced reality laparoscopic real‐time imaging to assess bowel perfusion at the anastomotic site in an experimental model. Br. J. Surg. 2015, 102, e169–e76.
  20. Diana, M.; Noll, E.; Diemunsch, P.; Dallemagne, B.; Benahmed, M.A.; Agnus, V.; Soler, L.; Barry, B.; Namer, I.J.; Demartines, N. et al. Enhanced-reality video fluorescence: A real-time assessment of intestinal viability. Ann. Surg. 2014, 259, 700–707.
  21. Barberio, M.; Longo, F.; Fiorillo, C.; Seeliger, B.; Mascagni, P.; Agnus, V.; Lindner, V.; Geny, B.; Charles, A.-L.; Gockel, I.; et al. HYPerspectral Enhanced Reality (HYPER): A physiology-based surgical guidance tool. Surg. Endosc. 2019, 34, 1736–1744.
  22. Barberio, M.; Felli, E.; Seyller, E.; Longo, F.; Chand, M.; Gockel, I.; Geny, B.; Swanström, L.; Marescaux, J.; Agnus, V. et al. Quantitative fluorescence angiography versus hyperspectral imaging to assess bowel ischemia: A comparative study in enhanced reality. Surgery 2020, 168, 178–184.
  23. Laemmel, E.; Genet, M.; Le Goualher, G.; Perchant, A.; Le Gargasson, J.-F.; Vicaut, E. Fibered confocal fluorescence microscopy (Cell-viZio™) facilitates extended imaging in the field of microcirculation. J. Vasc. Res. 2004, 41, 400–411.
  24. Diana, M.; Dallemagne, B.; Chung, H.; Nagao, Y.; Halvax, P.; Agnus, V.; Soler, L.; Lindner, V.; Demartines, N.; Diemunsch, P. et al. Probe-based confocal laser endomicroscopy and fluorescence-based enhanced reality for real-time assessment of intestinal microcirculation in a porcine model of sigmoid ischemia. Surg. Endosc. 2014, 2, 3224–3233.
  25. Schmidt, C.; Lautenschläger, C.; Petzold, B.; Sakr, Y.; Marx, G.; Stallmach, A. Confocal laser endomicroscopy reliably detects sepsis-related and treatment-associated changes in intestinal mucosal microcirculation. Br. J. Anaesth. 2013, 111, 996–1003.
  26. Diana, M.; Noll, E.; Charles, A.-L.; Diemunsch, P.; Geny, B.; Liu, Y.-Y.; Marchegiani, F.; Schiraldi, L.; Agnus, V.; Lindner, V. et al. Precision real-time evaluation of bowel perfusion: Accuracy of confocal endomicroscopy assessment of stoma in a controlled hemorrhagic shock model. Surg. Endosc. 2017, 31, 680–691.
  27. Urschel, J.D.; Antkowiak, J.G.; Delacure, M.D.; Takita, H. Ischemic conditioning (delay phenomenon) improves esophagogastric anastomotic wound healing in the rat. J. Surg. Oncol. 1997, 66, 254–256.
  28. Alfabet, C.; Montero, E.F.D.S.; Paes Leme, L.F.; Higashi, V.S.; Sallum Fo, C.F.; Fagundes, D.J.; Gomes, P.O. Progressive gastric perfusion in rats: Role of ischemic conditioning. Microsurg. Off. J. Int. Microsurg. Soc. Eur. Fed. Soc. Microsurg. 2003, 23, 513–516.
  29. Reavis, K.M.; Chang, E.Y.; Hunter, J.G.; Jobe, B.A. Utilization of the delay phenomenon improves blood flow and reduces collagen deposition in esophagogastric anastomoses. Ann. Surg. 2005, 241, 736.
  30. Lamas, S.; Azuara, D.; De Oca, J.; Sans, M.; Farran, L.; Alba, E.; Escalante, E.; Rafecas, A. Time course of necrosis/apoptosis and neovascularization during experimental gastric conditioning. Dis. Esophagus 2008, 21, 370–376.
  31. Quero, G.; Lapergola, A.; Barberio, M.; Seeliger, B.; Saccomandi, P.; Guerriero, L.; Mutter, D.; Saadi, A.; Worreth, M.; Marescaux, J. et al. Discrimination between arterial and venous bowel ischemia by computer-assisted analysis of the fluorescent signal. Surg. Endosc. 2019, 33, 1988–1997.
  32. Puxeddu, I.; Alian, A.; Piliponsky, A.M.; Ribatti, D.; Panet, A.; Levi-Schaffer, F. Human peripheral blood eosinophils induce angiogenesis. Int. J. Biochem. Cell Biol. 2005, 37, 628–636.
  33. Nissim Ben Efraim, A.H.; Levi-Schaffer, F. Roles of eosinophils in the modulation of angiogenesis. Chem Immunol Allergy 2014, 99, 138–154, doi:10.1159/000353251.
  34. Varricchi, G.; Loffredo, S.; Galdiero, M.R.; Marone, G.; Cristinziano, L.; Granata, F.; Marone, G. Innate effector cells in angiogenesis and lymphangiogenesis. Curr. Opin. Immunol. 2018, 53, 152–160.
  35. Staton, C.A.; Stribbling, S.M.; Tazzyman, S.; Hughes, R.; Brown, N.J.; Lewis, C.E. Current methods for assaying angiogenesis in vitro and in vivo. Int. J. Exp. Pathol. 2004, 85, 233–248.
  36. Akiyama, S.; Ito, S.; Sekiguchi, H.; Fujiwara, M.; Sakamoto, J.; Kondo, K.; Kasai, Y.; Ito, K.; Takagi, H. Preoperative embolization of gastric arteries for esophageal cancer. Surgery 1996, 120, 542–546.
  37. Diana, M.; Hübner, M.; Vuilleumier, H.; Bize, P.; Denys, A.; Demartines, N.; Schäfer, M. Redistribution of gastric blood flow by embolization of gastric arteries before esophagectomy. Ann. Thorac. Surg. 2011, 91, 1546–1551.
  38. Ghelfi, J.; Brichon, P.-Y.; Frandon, J.; Boussat, B.; Bricault, I.; Ferretti, G.; Guigard, S.; Sengel, C. Ischemic gastric conditioning by preoperative arterial embolization before oncologic esophagectomy: A Single-Center Experience. Cardiovasc. Interv. Radiol. 2017, 40, 712–720.
  39. Hölscher, A.H.; Schneider, P.M.; Gutschow, C.; Schröder, W. Laparoscopic ischemic conditioning of the stomach for esophageal replacement. Ann. Surg. 2007, 245, 241.
  40. Nguyen, N.T.; Nguyen, X.-M.T.; Reavis, K.M.; Elliott, C.; Masoomi, H.; Stamos, M.J. Minimally invasive esophagectomy with and without gastric ischemic conditioning. Surg. Endosc. 2012, 26, 1637–1641.
  41. Bludau, M.; Hölscher, A.; Vallböhmer, D.; Metzger, R.; Bollschweiler, E.; Schröder, W. Vascular endothelial growth factor expression following ischemic conditioning of the gastric conduit. Dis. Esophagus 2013, 26, 847–852.
  42. Veeramootoo, D.; Shore, A.C.; Shields, B.; Krishnadas, R.; Cooper, M.; Berrisford, R.G.; Wajed, S.A. Ischemic conditioning shows a time-dependant influence on the fate of the gastric conduit after minimally invasive esophagectomy. Surg. Endosc. 2010, 24, 1126–1131.
  43. Schröder, W.; Hölscher, A.H.; Bludau, M.; Vallböhmer, D.; Bollschweiler, E.; Gutschow, C. Ivor-Lewis esophagectomy with and without laparoscopic conditioning of the gastric conduit. World J. Surg. 2010, 34, 738–743.
  44. Berrisford, R.G.; Veeramootoo, D.; Parameswaran, R.; Krishnadas, R.; Wajed, S.A. Laparoscopic ischaemic conditioning of the stomach may reduce gastric-conduit morbidity following total minimally invasive oesophagectomy. Eur. J. Cardio-Thorac. Surg. 2009, 36, 888–893.
  45. El-Eishi, H.; Ayoub, S.; Abd-El-Khalek, M. The arterial supply of the human stomach. Cells Tissues Organs 1973, 86, 565–580.
  46. Akiyama, S.; Kodera, Y.; Sekiguchi, H.; Kasai, Y.; Kondo, K.; Ito, K.; Takagi, H. Preoperative embolization therapy for esophageal operation. J. Surg. Oncol. 1998, 69, 219–223.
More
© Text is available under the terms and conditions of the Creative Commons Attribution (CC BY) license; additional terms may apply. By using this site, you agree to the Terms and Conditions and Privacy Policy.
Upload a video for this entry
Information
Subjects: Oncology
Contributors MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register :
Manuel Barberio
,
Eric Felli
,
Raoul Pop
,
Margherita Pizzicannella
,
Bernard Geny
,
Veronique Lindner
,
Andrea Baiocchini
,
Boris Jansen-Winkeln
,
Yusef Moulla
,
Vincent Agnus
,
Jacques Marescaux
,
Ines Gockel
,
Michele Diana
View Times: 390
Revisions: 2 times (View History)
Update Date: 23 Oct 2020
Table of Contents
    1000/1000
    Hot Most Recent
    Feedback