Your search keyword '"Allendorf JD"' showing total 70 results

51. Residency, fellowships, and pseudo fellowships: whither general surgery?

Author

Widmann WD and Allendorf JD

Published

2002

52. A serum-soluble factor(s) stimulates tumor growth following laparotomy in a murine model.

Author

Lee SW, Gleason NR, Southall JC, Allendorf JD, Blanco I, Huang EH, Bessler M, and Whelan RL

Subjects

Animals, Female, Hot Temperature, Mice, Mice, Inbred BALB C, Mitosis, Molecular Weight, Pneumoperitoneum, Artificial, Tumor Cells, Cultured, Growth Substances blood, Laparotomy, Neoplasms, Experimental pathology

Abstract

Background: Our laboratory and others have previously demonstrated that tumors grow larger and are more easily established following laparotomy than after CO(2) pneumoperitoneum. The etiology of increased tumor growth after surgery is unknown. We hypothesized that, following laparotomy, a serum soluble factor(s) is generated that causes tumors to proliferate more rapidly. The purpose of the current study was to determine if in vitro tumor cells proliferate faster when incubated with serum from laparotomized mice than cells incubated with sera from mice who have undergone CO(2) pneumoperitoneum or anesthesia alone., Methods: In the first experiment, female Balb/C mice (n = 84) were randomly divided into the following three groups: (a) control (AC), (b) CO(2) insufflation (INS), and (c) laparotomy (OPEN). The AC mice underwent no procedure. The INS group underwent CO(2) pneumoperitoneum at 4-6 mmHg for 20 min. The OPEN group had a midline incision from xiphoid to pubis. The serum of seven mice from each group were collected on postoperative days (POD) 1, 2, 4, and 7 via a cardiac puncture. The sera at each time point for each group were pooled. Twenty thousand C-26 colon cancer cells were incubated separately in growth media containing 10% mouse serum from each group (seven determinations/group) at each time point. In the second experiment, female Balb/C (n = 30) mice were divided into AC and OPEN groups. On POD4, sera were collected and pooled. Three separate studies were performed for the second experiment. In the first study, tumor cells were incubated with 10% AC sera or varying concentrations of OPEN mice sera (4-10%). In the second study, aliquots of sera from the OPEN group mice were then heated at 100 degrees C for 1 or 5 min. Tumors were then incubated separately in media with 10% AC, OPEN, or heated OPEN group sera. In the third study, aliquots of sera from the OPEN group mice were dialyzed against PBS through a 3.5-kD or an 8-kD dialysis membrane tubing for 24 h. Tumors were then incubated separately in media with 10% AC, OPEN, or dialyzed OPEN group sera. For both experiments, tumor proliferation was determined and compared between groups after 72 h of incubation., Results: Tumor cells incubated with POD2 and POD4 sera from OPEN group mice proliferated twice as fast as those incubated with sera from either AC or INS group mice. The difference in proliferation was maximal on POD4 and started to decline by POD7. Proliferative activity from the OPEN group sera decreased significantly when heated for 1 min and was completely ablated after 5 min of heating. Proliferative activity from the OPEN group sera was completely ablated after dialysis., Conclusions: We conclude that there is a serum-soluble factor(s) present postoperatively that stimulates tumors to grow significantly faster after laparotomy. The mitogenic effect of laparotomized mice sera is dilutable. It is uncertain whether the factor is heat labile, since heating most likely destroys other necessary proteins in the sera. The size of the factor is undeterminable using the dialysis method. Further efforts to identify these factors are currently underway.

Published

2000

53. Delayed-type hypersensitivity response is better preserved in mice following insufflation than after laparotomy.

Author

Gleason NR, Blanco I, Allendorf JD, Lee SW, Zhai C, Bessler M, and Whelan RL

Subjects

Animals, Evaluation Studies as Topic, Female, Immunity, Cellular, Mice, Mice, Inbred C3H, Random Allocation, Disease Models, Animal, Hypersensitivity, Delayed immunology, Laparotomy, Pneumoperitoneum, Artificial

Abstract

Background: Our laboratory has previously used pig and rat models to demonstrate that delayed-type hypersensitivity (DTH) response to an antigen challenge is suppressed following laparotomy compared to insufflation. The purpose of this study was to develop a practical and reliable mouse DTH model that could be used in future studies to test immunomodulating drugs and therapies., Methods: Female C3H/HeN mice (n = 100) were given three serial DTH challenges of 25 microl of 4 mg/ml phytohemagglutinin (PHA) 12 days before the test procedure, immediately following the test procedure, and on the 2nd postoperative day. All challenges were administered via subcutaneous injection in alternating footpads. The thickness of the footpad was determined with electronic calipers immediately prior to injection and 24 h following injection in a blinded fashion. The difference in thickness represents the response. On the day of the procedure, mice were randomized into the following three groups: (a) control (AC), (b) insufflation (INS), and (c) open (OPEN). AC mice underwent no procedure. INS mice underwent CO(2) insufflation at 2-4 mmHg for 20 min. OPEN mice underwent a midline incision from xiphoid to pubis that was closed after 20 min. Data were analyzed using ANOVA and Tukey-Kramer tests to determine differences between groups., Results: Preoperatively, there were no significant differences among the three groups. On POD1, the OPEN group had significantly less response than both the AC and INS groups. On POD3, there were significant differences between the OPEN group and both the INS and AC groups. There was no significant difference between the AC and INS group at any time., Conclusions: In conclusion, a DTH mouse model has been established that allows serial assessment of cell-mediated immune function. This model can be used to study immune function after open and minimal access procedures in a simple and cost-effective manner.

Published

1999

54. Tumor proliferative index is higher in mice undergoing laparotomy vs. CO2 pneumoperitoneum.

Author

Lee SW, Southall JC, Allendorf JD, Bessler M, and Whelan RL

Subjects

Animals, Female, Mice, Mice, Inbred C3H, Postoperative Period, Proliferating Cell Nuclear Antigen analysis, Carbon Dioxide, Laparotomy, Mammary Neoplasms, Experimental pathology, Pneumoperitoneum, Artificial

Abstract

Purpose: Our laboratory has previously shown that tumors are more easily established and grow larger after laparotomy vs. laparoscopy. The purpose of this study was to better characterize these differences in tumor growth by assessing tumor cell proliferation via the proliferating cell nuclear antigen assay, which has been shown to be a reliable marker of cellular proliferation., Methods: Female C3H/He mice (N = 40) were inoculated intradermally in the dorsal skin with 10(6) cultured mouse mammary carcinoma cells <1 hour before interventions. Anesthesia control mice underwent no procedure. Laparotomy group mice had a midline incision from xiphoid to pubis that was closed after 20 minutes. Insufflation group mice underwent CO2 pneumoperitoneum (4-6 mmHg) for 20 minutes. On postoperative Day 6, tumors were excised from one-third of the mice in each group, and from the remaining mice on postoperative Day 12. Sections were made and stained immunohistochemically for proliferating cell nuclear antigen, and the proliferative index of each tumor was determined by taking the average of proliferating cell nuclear antigen-positive cells in five high-power fields (x450), counted in a blinded fashion with the aid of an optical grid., Results: On postoperative Day 6, the mean proliferative index for the laparotomy group was significantly higher than those for both the insufflation (P < 0.04) and the control (P < 0.001) groups. Of note, the proliferative index of the insufflation group was significantly higher than that of the control (P < 0.01) group. Similarly, on postoperative Day 12, the mean proliferative index for the laparotomy group was significantly higher than for both the insufflation (P < 0.05) and the control (P < 0.005) groups. The proliferative index in the insufflation group was also significantly higher than that of the control (P < 0.04) group., Conclusions: We have demonstrated that there is a significantly higher rate of tumor cell proliferation with the mouse mammary carcinoma cell tumor line after laparotomy than after pneumoperitoneum or anesthesia alone at two postoperative times. Additionally, insufflation alone increases postoperative tumor cell proliferation but to a lesser extent than laparotomy. The mechanism underlying these findings is unclear.

Published

1999

55. Increased tumor establishment and growth after open vs laparoscopic surgery in mice may be related to differences in postoperative T-cell function.

Author

Allendorf JD, Bessler M, Horvath KD, Marvin MR, Laird DA, and Whelan RL

Subjects

Animals, Female, Immunocompetence, Mice, Mice, Nude, Neoplasm Transplantation, Pneumoperitoneum, Artificial, Postoperative Period, Laparoscopy, Laparotomy, Mammary Neoplasms, Experimental immunology, T-Lymphocytes immunology

Abstract

Background: Previous work has demonstrated that cell-mediated immune function in rats is better preserved after laparoscopic than open surgery. We have also shown that tumors are more easily established in mice and grow larger after sham laparotomy than after pneumoperitoneum. The purpose of this study is to determine if the functional status of the cell-mediated immune system influences postoperative tumor growth., Methods: Immunocompetent (study 1) and T-cell deficient athymic (study 2) mice were injected with mouse mammary carcinoma cells in the dorsal skin. Mice then underwent either no procedure, midline laparotomy, or carbon dioxide pneumoperitoneum. Tumor masses on postoperative day 12 were compared., Results: In immunocompetent mice, laparotomy group tumors were nearly twice as large as laparoscopy group tumors (p < 0.02), which were 1.5 times as large as control group tumors (NS). In the athymic model, however, differences between the sham laparotomy and pneumoperitoneum groups were lost (p > 0.5). Tumors grew much larger in the athymic control mice than in the immunocompetent control mice (p < 0.01)., Conclusion: We conclude that T-cell function plays a significant role in host containment of mouse mammary carcinoma and in the mechanism of differences in tumor growth observed after laparotomy and pneumoperitoneum.

Published

1999

56. Wound tensile strength and contraction rate are not affected by laparotomy or pneumoperitoneum.

Author

Wickens JC, Whelan RL, Allendorf JD, Donahue J, Buxton E, McKee A, Panageas K, Gleason N, Lee S, and Bessler M

Subjects

Animals, Male, Rats, Rats, Sprague-Dawley, Tensile Strength, Laparotomy, Pneumoperitoneum, Artificial, Wound Healing

Abstract

Background: Many cellular elements responsible for wound healing are affected by laparotomy. The aim of this study was to evaluate the effects of laparotomy and CO2 pneumoperitoneum on wound healing., Methods: Male Sprague Dawley rats were randomly assigned to one of three experimental groups. Anesthesia control rats underwent no procedure. Pneumoperitoneum group rats were insufflated with CO2 gas. Laparotomy group rats underwent a 7-cm midline laparotomy incision. The interventions were 30 min long. For the incisional study (n = 30), a 4-cm dorsal full-thickness skin incision was made on each rat and then closed with staples. On postoperative days 7 and 14, an equal number of rats were sacrificed from each group, and wound tensile strength measurements were performed. For the excisional study (n = 45), each group of 15 rats underwent a 2-cm diameter circular dorsal full-thickness skin excision. Blinded measurements of wound area were performed every other day until wounds closed., Results: Wound tensile strength values were not significantly different among experimental groups at either time point. The study had a power of 80% to find a 30% difference at POD 7 and a power of 80% to find a 23% difference at POD 14 to a confidence level of p < 0.05. Wound contraction data from the excisional model were analyzed with the Generalized Estimation Equations statistical approach. When we modeled the treatment group as a covariate, no statistical difference was found between groups, demonstrating equal slopes across time., Conclusions: From the results of these studies, we conclude that wound healing in this model is not significantly diminished following laparotomy or peritoneal insufflation, as compared to anesthesia control.

Published

1998

57. General oncologic effects of the laparoscopic surgical approach. 1997 Frankfurt international meeting of animal laparoscopic researchers.

Author

Whelan RL, Allendorf JD, Gutt CN, Jacobi CA, Mutter D, Dorrance HR, Bessler M, and Bonjer HJ

Subjects

Animals, Carbon Dioxide adverse effects, Disease Models, Animal, Germany, Humans, Laparoscopy methods, Mice, Neoplasm Metastasis, Neoplasm Recurrence, Local etiology, Neoplasm Seeding, Pneumoperitoneum, Artificial adverse effects, Rats, Research, Risk Assessment, Tumor Cells, Cultured, Laparoscopy adverse effects, Neoplasms, Experimental surgery

Abstract

The results from the majority of the reviewed studies support the hypothesis that abdominal surgery, performed via either a large incision or CO2 pneumoperitoneum, systemically encourages tumor growth in the postoperative period. A full laparotomy incision appears to have a significantly greater effect than CO2 pneumoperitoneum on postoperative tumor growth. Whether the large tumor observed in the surgical groups are the result of increased tumor cell proliferation or diminished tumor cell death remains unclear. There is some evidence pointing to both mechanisms. The loss of the postoperative tumor growth differences between the open and pneumo animals in the athymic mouse experiment suggests that cell-mediated immune function plays a role in tumor containment. The proliferation study results, however, suggest that other stimulatory influence(s) are also at work. Clearly, much research needs to be done regarding the etiology of these tumor growth differences. Other tumor cell lines need to be studied, and investigations regarding tumor growth in an intra-abdominal location need be performed as well. This body of research suggests that the manner in which the surgeon gains access to the abdominal cavity may have an impact on the propensity of tumor cells to implant, survive, and grow in the period immediately after surgery. If true, this may be the most compelling justification for the use of minimally invasive techniques for the curative resection of malignancies. However, it remains to be proven that human tumors will demonstrate differences in tumor growth similar to those noted in some of these animals models. Furthermore, it is not all clear that slight differences in tumor growth postoperatively will translate into significant differences in long-term survival or recurrence rates. At first glance, the existence of port-site tumors would appear to contradict totally the conclusions of many studies discussed in this synopsis. If laparoscopic methods are associated with decreased rates of tumor growth and establishment, then why do port-site tumors form? This is a complex issue calling for discussion that goes far beyond the scope of this article. However, several brief comment on this topic follow. The etiology of port tumors is unknown, although traumatization of the tumor during mobilization, resection, or removal is likely to play a significant role in the liberation of tumor cells from the primary. A relatively small protective benefit, in terms of slower tumor growth rates in laparoscopic patients, will likely not be sufficient to prevent a large inoculum of viable tumor cells in an abdominal wound from establishing a metastasis. Furthermore, as suggested earlier, the systemic effects on tumor growth may be different from the local (i.e., intra-abdominal or abdominal wound) effects. Finally, the true incidence of port tumors remains unknown. It has not been definitively established that the laparoscopic wound tumor incidence is significantly higher than the open rate, although this is the assumption of most surgeons. Several relatively large recently published laparoscopic series have reported port tumor incidences of 0 to 1.2%, which is in the same "ballpark" as the 0.6 1.0% abdominal wound tumor incidences mentioned in several open colectomy series. Clearly, much more research in this area is needed to understand port tumors better and to reconcile the port tumor results with the systemic tumor growth benefits that may be associated with minimally invasive methods.

Published

1998

58. Increased tumor establishment and growth after open vs laparoscopic bowel resection in mice.

Author

Allendorf JD, Bessler M, Horvath KD, Marvin MR, Laird DA, and Whelan RL

Subjects

Animals, Cecostomy methods, Cell Death, Cell Division physiology, Chi-Square Distribution, Female, Immune Tolerance physiology, Laparoscopy mortality, Mammary Neoplasms, Experimental mortality, Mice, Mice, Inbred C3H, Neoplasm Recurrence, Local pathology, Reference Values, Surgical Procedures, Operative mortality, Survival Rate, Tumor Cells, Cultured cytology, Tumor Cells, Cultured immunology, Laparoscopy adverse effects, Mammary Neoplasms, Experimental surgery, Neoplasm Recurrence, Local etiology, Surgical Procedures, Operative adverse effects

Abstract

Background: Surgery can suppress immune function and facilitate tumor growth. Several studies have demonstrated better preservation of immune function following laparoscopic procedures. Our laboratory has also shown that tumors are more easily established and grow larger after sham laparotomy than after pneumoperitoneum in mice. The purpose of this study was to determine if the previously reported differences in tumor establishment and growth would persist in the setting of an intraabdominal manipulation., Methods: Syngeneic mice received intradermal injections of tumor cells and underwent either an open or laparoscopic cecal resection. In study 1, the incidence of tumor development was observed after a low dose inoculum; whereas in study 2, tumor mass was compared on postoperative day 12 after a high-dose inoculum., Results: In study 1, tumors were established in 5% of control mice, 30% of laparoscopy mice, and 83% of open surgery mice (p < 0.01 for all comparisons). In study 2, open surgery group tumors were 1.5 times as large as laparoscopy group tumors (p < 0.01), which were 1.5 times as large as control group tumors (p < 0.02)., Conclusion: We conclude that tumors are more easily established and grow larger after open laparoscopic bowel resection in mice.

Published

1998

59. An in vitro model fails to demonstrate aerosolization of tumor cells.

Author

Sellers GJ, Whelan RL, Allendorf JD, Gleason NR, Donahue J, Laird D, Bessler MD, and Treat MR

Subjects

Carbon Dioxide, In Vitro Techniques, Laparoscopy adverse effects, Neoplasm Seeding, Pneumoperitoneum, Artificial adverse effects, Tumor Cells, Cultured, Aerosols, Melanoma, Experimental

Abstract

Background: We investigated the ability of pressurized CO2 gas to aerosolize B16 melanoma (B16) tumor cells in an in vitro model., Methods: The experimental apparatus consisted of an 18.9-L plastic cylindrical vessel and a compliant latex pouch was attached to the top. Two 5-mm ports penetrated the vessel; insufflation and desufflation were carried out through them. A culture dish containing 20 million B16 cells in liquid culture media was placed at the base within the container. In the first experiment, the vessel was insufflated with CO2 gas to a static pressure of 15 or 30 mm Hg with the outflow port closed. After 10 min, the outflow port was opened and the gas was desufflated through a collecting device containing sterile culture medium. In a second experiment, a continuous flow of CO2 through the vessel was maintained after a pressure of 15 or 30 mm Hg was established. A total of 10 L CO2 was cycled through the vessel. In both experiments, 24 determinations were carried out at each pressure. Each experimental culture dish was microscopically scanned for 2 weeks for the presence of tumor cells. The third and fourth experiments tested for the presence of aerosolized nonviable tumor cells in the expelled gas. Using the model described above, after 10 mins of 30 mm Hg static pressure, the CO2 gas was expelled directly onto a glass slide and cytofixed. Alternately, after 10 mins at 30 mm Hg static pressure, the gas was expelled through a saline-filled Soluset (Abbott Laboratories), centrifuged, and the residue cytofixed onto a glass slide. Each of the five slides per experiment were examined microscopically for the presence of cells., Results: In the first and second experiments, no cells or growth were observed in any of the 96 experimental dishes. In experiments three and four, no cells were detected on any of the slides., Conclusions: It was not possible with this model to aerosolize tumor cells in a pressurized CO2 environment. Our results suggest that aerosolization of tumor cells is not the mechanism of port site recurrences after laparoscopic surgery for malignant disease.

Published

1998

60. Colon adenocarcinoma and B-16 melanoma grow larger following laparotomy vs. pneumoperitoneum in a murine model.

Author

Southall JC, Lee SW, Allendorf JD, Bessler M, and Whelan RL

Subjects

Animals, Female, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Pneumoperitoneum, Artificial adverse effects, Tumor Cells, Cultured, Adenocarcinoma pathology, Colonic Neoplasms pathology, Laparoscopy adverse effects, Laparotomy adverse effects, Melanoma, Experimental pathology, Neoplasm Transplantation pathology

Abstract

Purpose: Mouse mammary carcinoma tumors are established more easily and grow larger after sham laparotomy and open bowel resection than after CO2 pneumoperitoneum and laparoscopic-assisted bowel resection. The purpose of this study was to determine whether similar differences in tumor growth would be found when sham laparotomy and pneumoperitoneum were compared for the colon-26 mouse adenocarcinoma and B-16 mouse melanoma tumor lines., Methods: In all three studies, a high-dose injection of tumor cells was used, which resulted in tumors in almost all control mice. In Study 1, female BALB/C mice (n = 127) were injected intradermally in the dorsal skin with 10(6) colon-26 cells in a 0.1-ml volume before interventions. In Study 2, female C57 BL/6 mice (n = 140) were inoculated similarly with 10(6) B-16 melanoma cells. Study 2 consisted of three separate trials conducted on different days. Study 3 was performed because considerable differences in mean tumor size were observed in each of these trials. In Study 3, the B16 experiment was repeated with a larger n (n = 82) on a single day. In each study, after tumor cell injections, mice were randomly assigned to one of three groups: 1) anesthesia control (no procedure); 2) full laparotomy (4-cm midline incision x 20 minutes, staple closure); or 3) CO2 pneumoperitoneum (4-6 mmHg X 20 minutes). Tumors were excised and weighed on postoperative day 12., Results: In Studies 1 and 3, mean tumor sizes of the laparotomy groups were significantly larger than both the control group and pneumoperitoneum group lesions (P values by Student's t-test). In Study 2, laparotomy group tumors, although significantly larger than control group lesions, were not significantly larger than pneumoperitoneum group tumors. For all three studies, there was no significant difference between mean tumor sizes of the pneumoperitoneum and control groups., Conclusion: Both colon-26 adenocarcinoma and B-16 melanoma tumors grow larger after laparotomy than after pneumoperitoneum in a murine model. The mechanism of these postoperative tumor growth differences remains to be elucidated.

Published

1998

61. The effect of peritoneal air exposure on postoperative tumor growth.

Author

Southall JC, Lee SW, Bessler M, Allendorf JD, and Whelan RL

Subjects

Air, Animals, Carbon Dioxide, Evaluation Studies as Topic, Female, Immune Tolerance, Immunocompetence, Mice, Mice, Inbred C3H, Random Allocation, Tumor Cells, Cultured, Mammary Neoplasms, Experimental surgery, Pneumoperitoneum, Artificial

Abstract

Background: Previous work has demonstrated that cell-mediated immune function is better preserved in rodents after laparoscopic than open surgery. The cause of this laparotomy-related immunosuppression is unclear. Some investigators have attributed it to the length of the incision; others, to peritoneal air exposure. It has also been shown that tumors in mice are more easily established and grow larger after sham laparotomy than after pneumoperitoneum. Lastly, the differences in tumor growth have been shown to be, at least in part, attributable to the immunosuppression that occurs after laparotomy. The purpose of this study was to determine if air pneumoperitoneum, presumably via immunosuppression related to peritoneal air exposure, is associated with increased tumor growth in the postoperative period., Method: A total of 150 immunocompetent syngeneic mice received high-dose intradermal injections of mouse mammary carcinoma tumor cells. They were then randomized to undergo one of the following procedures: (a) anesthesia alone, (b) air insufflation (44 mm Hg), (c) CO2 insufflation, or (d) full laparotomy. No intraabdominal procedure was carried out. All procedures were 20 min long. After 12 days, the animals were killed and the mean tumor mass determined for each group., Results: All animals grew tumors. There was no significant difference in the mean tumor size of the anesthesia control, CO2 insufflation, and air insufflation groups (p > 0.85 by ANOVA). However, the laparotomy group tumors were 1.5 times as large as those of the other three groups (p < 0.05 by ANOVA)., Conclusions: In this model, air insufflation did not significantly affect postoperative tumor growth, nor did CO2 pneumoperitoneum. However, full laparotomy was associated with increased tumor growth.

Published

1998

62. A murine model of laparoscopic-assisted intervention.

Author

Allendorf JD, Bessler M, and Whelan RL

Subjects

Animals, Female, Intraoperative Complications, Mice, Mice, Inbred C3H, Reproducibility of Results, Safety, Cecum surgery, Disease Models, Animal, Laparoscopy methods, Laparoscopy standards

Abstract

Background: In order to better investigate the effects of laparoscopic surgery, it is necessary to establish reliable, reproducible, and economical animal models of laparoscopic intervention. Here we describe a mouse model of laparoscopic-assisted colon resection., Methods: After successful induction of anesthesia the mouse is placed in Trendelenburg position and the peritoneal cavity is insufflated with carbon dioxide gas through an angiocatheter placed in the right upper quadrant. A 4-mm rigid scope with camera attachment is then inserted through a midline port created just caudal to the xiphoid. A second port is then created in the right lower quadrant to allow introduction of laparoscopic forceps into the peritoneal cavity. The cecum, which extends 1.5 cm beyond the ileocecal valve, is grasped with forceps and exteriorized through the operative port. Extracorporeally, the cecum is ligated and resected before the cecal stump is returned to the peritoneal cavity. The abdominal wall defects are then stapled closed., Results: This simple model can be mastered by individuals with very limited surgical experience. This laparoscopic model has been used successfully in our laboratory in a number of experiments with an intraoperative complication rate of 3. 2% (3/94), which was similar to the open surgery group rate of 2.1% (2/95, p = 0.99 by chi square). We observed no postoperative leaks in either group. The only postoperative death occurred in the open resection group due to dehiscence of the laparotomy wound., Conclusions: We propose that this model may be useful for comparing the effects of open to laparoscopic surgery.

Published

1997

63. Postoperative immune function varies inversely with the degree of surgical trauma in a murine model.

Author

Allendorf JD, Bessler M, Whelan RL, Trokel M, Laird DA, Terry MB, and Treat MR

Subjects

Analysis of Variance, Animals, Hypersensitivity, Delayed immunology, Laparotomy, Male, Phytohemagglutinins administration & dosage, Postoperative Period, Rats, Rats, Sprague-Dawley, Time Factors, Cecum surgery, Immunity, Cellular, Laparoscopy methods, Laparoscopy statistics & numerical data

Abstract

Background: Major surgery through a laparotomy incision is associated with a postoperative reduction in immune function. Studies in rats involving sham procedures suggest that immune function may be preserved after laparoscopy. This study investigates the effects of incision length and exposure method for bowel resection with respect to postoperative immune function as assessed by delayed-type hypersensitivity (DTH) reactions., Methods: Male Sprague Dawley rats (n = 175) were challenged preoperatively, immediately postoperatively, and on postoperative day 2 with an intradermal injection of 0.2 mg phytohemagglutinin (PHA), a nonspecific T-cell mitogen. The averages of two measures of perpendicular diameters were used to calculate the area of induration. Anesthesia control rats underwent no procedure. Minilaparotomy rats underwent a 3.5-cm midline incision. Sham full laparotomy rats underwent a 7-cm midline incision. The open bowel-resection group underwent a cecal ligation and resection through a 7-cm midline incision. In the laparoscopic-assisted resection group a CO2 pneumoperitoneum and four-port technique was utilized to deliver the cecum through a 4-mm port where the cecum was extracorporeally ligated and resected., Results: Preoperative responses were similar in all five groups. Incision length: Full laparotomy group responses were 20% smaller than anesthesia control responses on postoperative day (POD)1 through POD4 (p < 0.02). At no time point were the responses in the minilaparotomy group significantly different from either anesthesia control or full laparotomy group responses. Exposure method: The laparoscopic-assisted resection group responses were 20% larger than open group responses at the time of two of the four postoperative measurements (p < 0.05, both comparisons). At all postoperative time points, open resection group responses were significantly smaller than control responses (p < 0.05, all comparisons), whereas at no time point were laparoscopic group responses significantly different from control responses., Conclusion: We conclude that postoperative cell-mediated immune function varies inversely with the degree of surgical trauma. Results from the minilaparotomy and laparoscopy groups suggest that procedures done through small incisions may result in preservation of postoperative immune function.

Published

1997

64. Helium-neon laser irradiation at fluences of 1, 2, and 4 J/cm2 failed to accelerate wound healing as assessed by both wound contracture rate and tensile strength.

Author

Allendorf JD, Bessler M, Huang J, Kayton ML, Laird D, Nowygrod R, and Treat MR

Subjects

Animals, Male, Rats, Rats, Sprague-Dawley, Tensile Strength, Wound Healing physiology, Laser Therapy, Wound Healing radiation effects

Abstract

Background and Objective: Reports in the literature indicate that low energy laser irradiation has a biostimulatory effect on wound healing; however, no mechanism of this effect has been elucidated., Study Design/materials and Methods: We attempted to establish a model from which to study the mechanism of biostimulation. The effects of low energy helium-neon irradiation on wound healing were observed in two rat models. In the first model, 1.5 cm diameter full thickness excisional skin defects were created in the dorsal midline of rats (n = 32). All animals were anesthetized and all eschars were debrided daily. Wound area was determined by caliper measurements for 2 weeks postoperatively. Rats that received a treatment of 1 J/cm2 had two defects in the dorsal skin. One wound was treated and the second was used as its own control. These measurements were not blinded. Rats that received 2 J/cm2, 4 J/cm2, or anesthesia alone had one defect on the dorsal skin. Caliper measurements of these wounds were blinded. We were unable to demonstrate any difference in the rate of wound contracture in rats that received a daily dose of 1 J/cm2, 2 J/cm2, 4 J/cm2, or anesthesia alone (P > 0.8 by student's t-test). In the second model, a single 2 cm longitudinal full thickness skin incision was created in the dorsal midline of each rat (n = 24). No difference was found between rats that received anesthesia alone and those treated daily with 2 J/cm2 as assessed by tensile strength measurements on postoperative days 7 and 14 (P > 0.8 by student's t-test between groups at both time points). These determinations were blinded., Results: Despite our intentions of studying the mechanism of low energy HeNe biostimulation, we were unable to demonstrate a beneficial effect., Conclusion: In this study, helium-neon laser irradiation produced no measurable benefit on wound healing.

Published

1997

65. Better preservation of immune function after laparoscopic-assisted vs. open bowel resection in a murine model.

Author

Allendorf JD, Bessler M, Whelan RL, Trokel M, Laird DA, Terry MB, and Treat MR

Subjects

Animals, Disease Models, Animal, Hemocyanins, Hypersensitivity, Delayed diagnosis, Immunity, Cellular, Male, Phytohemagglutinins, Rats, Rats, Sprague-Dawley, Skin Tests, Time Factors, Colectomy adverse effects, Hypersensitivity, Delayed etiology, Immune Tolerance immunology, Laparoscopy adverse effects, Laparotomy adverse effects

Abstract

Unlabelled: We evaluated cell-mediated immune function after laparoscopic-assisted and open bowel resection in rats by measuring delayed-type hypersensitivity responses to keyhole limpet hemocyanin (KLH) and phytohemagglutinin (PHA)., Methods: Male Sprague-Dawley rats (n = 120) were sensitized to 1 mg of KLH ten days before investigations. Rats were challenged preoperatively, immediately postoperatively, and on postoperative day (POD) 2 with an intradermal injection of 0.3 mg of KLH and 0.2 mg of PHA (at different sites). Averages of two measures of perpendicular diameters (taken 24 and 48 hours postchallenge) were used to calculate the area of induration using the formula for the area of an ellipse, A = (D1/2 x D2/2) x pi. Anesthesia control animals underwent no procedure (n = 40). Open resection group underwent ligation and resection of the cecum (length = 2 cm) through a 7 cm midline incision (n = 40). In the laparoscopic-assisted resection group, under CO2 pneumoperitoneum (4-6 mmHg), the cecum was identified, dissected free, and exteriorized through a 4 mm port. The cecum was then ligated and resected extracorporeally (n = 40)., Results: Preoperative responses to both KLH and PHA were the same in all three groups. Furthermore, within each group, postoperative responses were similar. When groups were compared, the anesthesia group responses were significantly greater than the open resection group responses at all time points (P < 0.05 for all comparisons). Laparoscopic assisted resection group responses differed from control at only two of eight postoperative measures. Laparoscopic resection group responses were significantly greater than open resection group responses to challenge with both KLH and PHA on POD1 (P < 0.02, for both comparisons) and POD 4 (P < 0.05, for both comparisons)., Conclusions: Postoperative cell-mediated immune function is better preserved after laparoscopic-assisted bowel resection than after open resection as assessed by skin antigen testing.

Published

1996

66. Trocar site recurrence is unlikely to result from aerosolization of tumor cells.

Author

Whelan RL, Sellers GJ, Allendorf JD, Laird D, Bessler MD, Nowygrod R, and Treat MR

Subjects

Aerosols, Animals, Carbon Dioxide, Colonic Neoplasms, Disease Models, Animal, Male, Melanoma, Experimental, Peritoneal Lavage, Pressure, Rats, Rats, Sprague-Dawley, Surgical Wound Infection, Tumor Cells, Cultured, Colectomy adverse effects, Laparoscopy adverse effects, Neoplasm Seeding, Pneumoperitoneum, Artificial adverse effects

Abstract

Purpose: This study was undertaken to investigate the ability of a high-pressure CO2 environment to aerosolize tumor cells in both in vitro and in vivo models. (An aerosol is defined as a stable gaseous suspension of insoluble particles). Also, this study was designed to determine if rapid desufflation is capable of transporting fluid laden with tumor cells., Methods: The four in vitro aerosol experiments were performed in an 18.9-1 plastic vessel fitted with two 7-mm ports and a compliant latex balloon affixed to the top. After CO2 insufflation, the vessel was desufflated through a sterile soluset containing 25 ml of culture media that was subsequently emptied into a culture dish, incubated for two weeks, and periodically assessed for growth. At the bottom of the vessel, one of the following was placed: Study 1 and 2, a suspension of B16 melanoma or colon 26 tumor cells in liquid culture media; Study 3, colon 26 cells in saline solution; Study 4, several pieces of solid colon 26 tumor. In Studies 1 to 3, cell preparations were subjected to the following high-pressure CO2 conditions (pneumo): 1) static pneumo of 15 and 30 mmHg (10 minute dwell); 2) a continuous flow (CF) of CO2 (1O l) while maintaining a pressure of 15 or 30 mmHg in the vessel. In Study 4, only the 30 mmHg static and CF conditions were tested. Between 6 and 12 determinations were performed for each condition and cell preparation. In vivo aerosol experiments consisted of Spraque Dawley rats that received intraperitoneal injections of 10-5 B16 cells in 0.1 ml of liquid media. Two laparoscopic ports were placed in the abdomen, one each for insufflation and desufflation. Study groups were: 1, static CO2 pneumo of 15 mmHg; 2 and 3, continuous CO2 flow (10 l) at a stable pneumo pressure of 5 and 10 mmHg. Desufflation was performed via the same collecting device and handled in an identical manner to the in vitro experiments described above. The in vitro balloon experiment was designed to investigate the ability of desufflation to transport fluid-containing tumor cells; latex balloon model was used. To prevent complete loss of volume on desufflation, a wire coil was placed inside the balloon. Twenty ml of media containing 20 x 10(-6) B16 cells was placed in the bottom of the balloon. The balloon was insufflated with 1 to 2 l of gas. There were three study groups that differed in the degree to which the cell suspension was agitated before desufflation. Study conditions were as follows: 1) no agitation; 2) moderate agitation to coat the lower walls and coil; 3) maximum agitation to coat the entire balloon. To verify the viability of tumor cells, at the end of each in vitro and in vivo study, a sample of tumor cells or peritoneal washing was incubated in sterile media. These samples served as positive controls., Results: In vitro aerosol studies consisted of the following. At the end of two weeks of incubation, no tumor growth was noted in any of the 124 test dishes. The 14 control samples all demonstrated tumor growth. In vivo aerosol studies consisted of the following. Zero of 18 experimental dishes grew tumor. All three peritoneal washing samples demonstrated growth. In vitro balloon studies consisted of the following. Zero of 12 test dishes in Groups 1 and 2 demonstrated growth, whereas five of six dishes did so in Group 3 (maximally agitated before desufflation). Again, positive controls all grew tumor cells., Summary: We were unable to demonstrate aerosol formation in any of the in vitro and in vivo studies performed. In the balloon experiment, desufflation-related transport of tumor cells was demonstrated but only when the entire balloon surface was coated with the tumor cell suspension before desufflation., Conclusion: Aerosols of tumor cells are not likely to form. Free intraperitoneal tumor cells are most likely found in liquid suspension. Desufflation is a potential means of transport of cell-laden fluid.

Published

1996

67. Transluminal aortic valve placement. A feasibility study with a newly designed collapsible aortic valve.

Author

Moazami N, Bessler M, Argenziano M, Choudhri AF, Cabreriza SE, Allendorf JD, Rose EA, and Oz MC

Subjects

Animals, Aortic Valve diagnostic imaging, Aortic Valve physiology, Cardiac Catheterization, Cattle, Evaluation Studies as Topic, Hemodynamics, Humans, In Vitro Techniques, Pericardium, Prosthesis Design, Stents, Swine, Ultrasonography, Aortic Valve surgery, Bioprosthesis, Heart Valve Prosthesis

Abstract

Percutaneous stents are used in vascular applications in conjunction with angioplasty and in combination with graft material for repair of abdominal aneurysms. The authors have designed a collapsible bioprosthetic aortic valve for placement by a transluminal catheter technique. This trileaflet stent valve is composed of stainless steel and bovine pericardium. Stent valves, 23 and 29 mm, were tested in a pulse duplicator system with rigid rings from 21 to 31 mm in 2 mm increments. At a mean flow of 3.1 L/min (+/-0.7), normal systemic aortic pressure was generated with a transvalvular gradient of 14.9 +/- 7 mmHg (mean +/- SD). Regurgitation fraction ranged from 10 to 18% (mean 13.8 +/- 3%) in the best ring size. Valves with the best hemodynamic profile were used for implantation in three 70 kg pigs in an open chest model. The valve was collapsed in a 24 Fr catheter designed to allow slow, controlled release. After resection of the native leaflets, the new valve was placed in the subcoronary position. No additional sutures were used for securing the valve. Two animals were successfully weaned from cardiopulmonary bypass and maintained systemic pressures of 100/45 (+/-10) and 116/70 (+/-15) mmHg, respectively. Intraoperative color echocardiography revealed minimal regurgitation, central flow, full apposition of all leaflets, and no interference with coronary blood flow. Both animals were sacrificed after being off bypass for 2 hr. Postmortem examination revealed the valves to be securely anchored. The third animal was weaned from cardiopulmonary bypass but developed refractory ventricular fibrillation because of valve dislodgment due to structural failure. Although long term survival data are needed, development of a hemodynamically acceptable prosthetic aortic valve for transluminal placement is feasible.

Published

1996

68. Controlled trial of laparoscopic-assisted vs open colon resection in a porcine model.

Author

Bessler M, Whelan RL, Halverson A, Allendorf JD, Nowygrod R, and Treat MR

Subjects

Anastomosis, Surgical instrumentation, Animals, Colon pathology, Feasibility Studies, Lymph Node Excision instrumentation, Postoperative Complications pathology, Swine, Tissue Adhesions, Treatment Outcome, Colectomy instrumentation, Laparoscopes

Abstract

Background: Several series of laparoscopic colon resection have been reported in the literature with varied results; however, no controlled series of laparoscopic vs open colon resection has been reported. The purpose of this study was to determine the relative safety and adequacy of laparoscopic colon resection in a controlled trial using a porcine model., Methods: Domestic pigs (n = 23) were randomly divided into two groups. Animals underwent either an open or laparoscopic-assisted segmental resection of the sigmoid colon. The open resections were performed through a 20-cm midline incision and the laparoscopic technique utilized five 12-mm ports. Laparoscopic resection took twice as long to complete as open resection (P < 0.001). Return of gastric function was significantly faster in the laparoscopic group than in the open group (P < 0.032)., Results: No significant differences were found in total length of resection, proximal or distal margins, number of lymph nodes recovered, length of mesenteric vessel resected, or time to return of bowel function. At vivisection, more adhesions to the abdominal wall were noted in the open group (P < 0.002). One death occurred in the laparoscopic group 2 h postoperatively (8.3% mortality) while all open group pigs survived. However, there was no statistically significant difference in mortality rates by chi-square analysis (P > 0.5)., Conclusions: Despite longer operative time, laparoscopic intervention is technically feasible, safe, and may offer significant postoperative benefits due to fewer abdominal adhesions.

Published

1996

69. Increased tumor establishment and growth after laparotomy vs laparoscopy in a murine model.

Author

Allendorf JD, Bessler M, Kayton ML, Oesterling SD, Treat MR, Nowygrod R, and Whelan RL

Subjects

Animals, Cell Division, Female, Mice, Mice, Inbred C3H, Random Allocation, Time Factors, Tumor Cells, Cultured, Laparoscopy, Laparotomy, Neoplasm Transplantation pathology

Abstract

Objective: To test our hypothesis that tumors would be more easily established and grow more aggressively after laparotomy than after laparoscopy. This hypothesis was based on studies that have demonstrated that surgery can suppress immune function and facilitate tumor growth and that have shown preservation of immune function after laparoscopic procedures., Design: Double-blinded, randomized, control trial., Setting: Research laboratory and animal care facility., Animals: One hundred forty 5- to 6-week-old C3H/He female mice., Interventions: Three experiments with three groups each: laparotomy, insufflation, and anesthesia controls. All animals received an intradermal inoculation of tumor cells in the dorsal skin. The anesthesia control cohort underwent no procedure. The laparotomy cohort underwent a midline laparotomy from the xiphoid process to the pubis, which was closed after 30 minutes. The insufflation cohort underwent peritoneal insufflation with carbon dioxide for 30 minutes., Main Outcome Measures: Tumor volume, tumor mass, and incidence of tumor establishment., Results: In the first experiment, the tumor volumes of the anesthesia control and insufflation groups followed a similar pattern of plateau and regression. The tumor volumes of the laparotomy group followed a different pattern and were significantly larger than those of the control and insufflation groups on postoperative days 6 and 12 (P < .05 for all comparisons). In the second experiment, tumors in the laparotomy group were approximately three times larger than those of the control group (P < .01) and almost twice as large as insufflation group tumors (P < .01) by mass. In the third experiment, there was a significantly higher incidence of tumor establishment in the laparotomy group than in the insufflation (P < .04) or control (P < .01) groups. The incidence was not different between the control and insufflation groups., Conclusions: Tumors were more easily established and grew more aggressively after laparotomy than after insufflation. These results, coupled with those that demonstrate an immune advantage to laparoscopy over laparotomy, suggest that the difference in observed tumor growth may be related to immune function. While much work remains to be done, we believe these data provide evidence of a previously undemonstrated benefit of laparoscopic intervention.

Published

1995

70. Tumor growth after laparotomy or laparoscopy. A preliminary study.

Author

Allendorf JD, Bessler M, Kayton ML, Whelan RL, Treat MR, and Nowygrod R

Subjects

Animals, Female, Immune Tolerance, Insufflation adverse effects, Mammary Neoplasms, Experimental pathology, Mice, Mice, Inbred C3H, Neoplasm Transplantation, Tumor Cells, Cultured, Laparoscopy adverse effects, Laparotomy adverse effects, Peritoneal Neoplasms pathology

Abstract

We investigated the effects of laparotomy and insufflation on tumor establishment and growth in a murine model. Twenty female mice received intradermal inoculation of a low dose of tumor cells (2 x 10(3)) derived from the MC2 mouse mammary carcinoma cell line. Ten of these mice underwent laparotomy and ten received intraperitoneal insufflation with carbon dioxide gas at a pressure of 5 mmHg for 30 min. Tumor growth was followed postoperatively. By postoperative day 14, tumors had grown in zero of the ten insufflated mice and in seven of the ten laparotomy-group mice (P < 0.005). By postoperative day 30, tumors had grown in one of the ten insufflated mice and in eight of the ten laparotomy-group mice (P < 0.007). Ten additional mice received a high-dose inoculum of cells (1 x 10(6)) followed by either laparotomy or intraperitoneal insufflation. Upon sacrifice 12 days later, all mice had developed tumors, but the laparotomy group's tumors were almost three times as large, by mass, as tumors in the insufflated group (70.5 +/- 23.5 mg vs 25.8 +/- 9.5 mg; P < 0.02). These results suggest that laparotomy confers a permissive effect on tumor establishment and growth in a murine model not seen after peritoneal insufflation. We hypothesize that this may be a function of relative immunosuppression following laparotomy which is not present following peritoneal insufflation. These data may be important when choosing a route of access to the peritoneal cavity for cancer resection.

Published

1995