Less commonly, perforations may be retroperitoneal (as can occur in the distal rectum) and walled off. In these cases, free air will not be identified on abdominal X‐ray. In these cases, CT scanning would be needed to identify and locate the problem. These can often be managed more conservatively with fasting and IV antibiotics with close inpatient monitoring. Occasionally, incidental radiographic findings of free air in the peritoneal cavity occur following endoscopy, yet in the absence of any clinical symptoms of perforation. The clinical significance, if any, of these findings is unclear, yet conservative management and close observation also is recommended.
Training fellows to manage perforations is difficult, as these do not occur often. The main teaching point is to never underappreciate or deny to oneself the possibility of a perforation. If there is any suspicion that a perforation has occurred, this needs to be aggressively pursued with diagnostic and therapeutic intervention as needed. In the event of a perforation, it is also paramount that the endoscopist personally stays in direct communication with the patient and family and not to simply ship the patient off to the emergency room and distance oneself from the case.
Intermediate motor skills
Loop reduction
One of the hardest skills for trainees to master is the prevention and adequate reduction of loops that develop during scope advancement. This section will address the common types and locations of loops that form and how to manage these effectively. One key concept to understand with loop formation is that of “force vectors.” Force vectors are where and in what direction the majority of the pushing force is being delivered in the colon. If a scope is perfectly straight, all of the force is being translated directly into tip advancement. If there is a 90° or greater turn, much of this force is directed at the wall of the colon on the outside part of the turn (Figure 6.21). As the wall pushes back, some of this opposing force gets delivered forward to the scope tip, resulting in advancement, some back to the operator as resistance and some absorbed by the elastic nature of the colon wall as a loop. Reducing and straightening these loops not only removes the force against the colon wall but with correct technique can also result in prevention of recurrent loop formation and better delivery of the pushing force to the scope tip.
Figure 6.21 Force vector. In this illustration, the tip of the scope is deflected greater than 90° around an acute turn in the colon. In this configuration, the force vector (FV) of any attempts to advance the colon will be directed against the wall of the colon on the outside turn. This will be felt by the endoscopist as resistance to advancement or will result in looping of the scope shaft here or elsewhere in the colon.
(Copyrighted and used with permission of Mayo Foundation for Medical Education and Research.)
The sigmoid colon is the location where most loops occur. This is due to the serpentine nature of this section of colon accompanied by the fact that it is freely mobile within the abdominal cavity. The most common natural course of the sigmoid is a clockwise spiral between the rectum and descending colon. As the tip of the scope makes the first acute turn from the rectum into the sigmoid and the scope is advanced, the shaft of the scope behind the flexible scope tip tends to be pushed upward in the abdomen as the force vector of the scope is still relatively straight‐in from the anus and rectum (Figure 6.22). This results in loss of “one‐to‐one” motion; a term meaning the scope is not advancing as much (or not at all) as the shaft of the scope is being pushed in. This extra inserted scope that is not resulting into tip advancement is instead contributing to the development of a loop. Looping can also result in “paradoxical movement” of the scope, which is when the scope tip actually moves in the opposite direction as the shaft is pushed or pulled.
Figure 6.22 Sigmoid loop. As the scope makes multiple turns in the sigmoid colon, advancing the scope frequently results in the force being transmitted laterally against the sigmoid walls (arrows) resulting in loop formation.
(Copyrighted and used with permission of Mayo Foundation for Medical Education and Research.)
Figure 6.23 Alpha‐loop. One of the most common types of sigmoid loop formation is the alpha‐loop. This can be reduced with clockwise torque of the scope shaft as it is slowly pulled back. Once the loop is reduced, the scope shaft is again straight and can be readily advanced again.
(Copyrighted and used with permission of Mayo Foundation for Medical Education and Research.)