Intraoperative radiation therapy (IORT)

Intraoperative radiation therapy (IORT)
Anesthesia type	General
Airway	ETT
Lines and access	PIV x2 +/- Arterial line +/- Central line
Monitors	Standard BIS +/- ABP +/- CVP
	Primary anesthetic considerations
Preoperative	Frailty, chemotherapy sequelae (pancytopenia), tumor size and location, "full stomach"
Intraoperative	Access, resuscitation, equipment contingencies
Postoperative	Potential ICU transport, ongoing resuscitation
	Article quality
Editor rating	Unrated
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Intraoperative radiotherapy (IORT) is designed to provide a large radiation dose to a target tissue while sparing normal tissues. The therapeutic advantage is derived by delivering low-energy photons or electrons to a tumor bed with a gross total or near gross total resection, thereby allowing a steep dose fall off, which will spare normal tissues. IORT is often combined with external-beam radiation therapy (EBRT) to provide the best combination of local and locoregional treatment^[1]^[2]. It does, however, require an invasive surgical procedure to locally treat the tumor. It can be used to treat breast, head & neck, pelvic^[3], and gastrointestinal^[4] malignancies. IORT can be delivered by using Linac-based electron beam radiation therapy (IOERT), low-energy photons, or by high-dose-rate brachytherapy catheters (HDR-IORT). All of these techniques deliver high doses of radiation to the target site while protecting normal surrounding structures through retraction or shielding using lead sheets^[5].

These procedures are resource intensive and require complex patient selection and logistical planning. An IORT program requires the combined planning and efforts of surgical and/or medical oncology, radiation oncology, OR staff, and anesthesiology.

Overview

Indications

Subtotal resection of malignancy
Recurrent malignancy for which external beam radiation is deemed unsafe

Surgical procedure

The basic principles are well described by Debenham et al^[1]

Resection

The first step is total or sub-total resection of tumor

Whether the tumor is large or small, the IORT equipment usually requires a large laparotomy
Each tumor is different and will carry distinct risks in terms of bleeding potential, compression of vital structures, invasion of large vessels

Intraoperative Radiation

The next step is positioning the radiation equipment

The radiation oncology team decides on technique, dose, and equipment
Some equipment require special lead shielded rooms or other radiation barriers, while others are self shielding
Generally once the equipment is positioned correctly, everyone must leave the room during treatment so as not to be exposed to radiation. Treatment times vary, but are usually 5-10 minutes. Confirm with the surgeon and radiation oncologist how long they plan on treating
- Every institution approaches monitoring during this time differently, some use cameras, some place monitors at windows, some have shielded subrooms in the OR
- Whatever approach is used, the goal is to have the patient in a steady, stable state at the time of treatment. If you are not in a stable state, inform the surgical team that you need to stabilize the patient prior to proceeding with treatment
- Discuss with the surgeon, radiation oncologist, and physicists what the protocol is for ending treatment and re-entering the room in case of emergency. Generally, the radiation equipment can be turned off quickly and once turned off it is safe to enter the room

Closure

The final step is finalizing any remaining surgical procedures and closure

Preoperative management

Patient evaluation


System	Considerations
Airway	Large abdominal tumors or patients with ascites may require RSI
Neurologic	Neoadjuvent chemotherapy or radiation can cause neuropathy
Cardiovascular	Standard evaluation
Pulmonary	Standard evaluation
Gastrointestinal	Tumor size, location, possible compression or invasion of other structures
Hematologic	Pancytopenia in setting of chemotherapy
Renal	Standard evaluation
Endocrine	Standard evaluation

Labs and studies

Type and screen - cross units depending on patient and procedure
CBC
+/- EKG, TTE, stress test
Otherwise indicated by history and presentation

Operating room setup

Arterial catheter and transducer
Fluid warmer
Infusion pumps
Vasopressor infusions available
Push dose pressors
+/- blood tubing

Patient preparation and premedication

Standard

Regional and neuraxial techniques

Useful for multimodal pain control
Epidurals are frequently used for intraoperative autonomic control and postoperative pain control for abdominal or thoracic tumors
- If epidural contraindicated, regional blocks can be used for postoperative pain control

Intraoperative management

Monitoring and access

PIV x2
Standard monitors
Frequently radial arterial line
Central line as indicated by tumor and patient

Induction and airway management

Standard
- For abdominal tumors cosider RSI

Positioning

Standard, depends on tumor location and planned procedure

Maintenance and surgical considerations

Standard maintenance, patient is chemically paralyzed to assist with adequate surgical exposure and ensure immobility during radiation treatment
IORT procedures are highly variable in terms of tumor size, position, vascularity, etc. and, therefore, need to be approached on a case by case basis in terms of planning induction, intubation, access, and blood product preparation
Review imaging and discuss with surgeons their expectation for the extent of resection and possible difficulties to help guide your decisions about access and preparation
Stay in communication with the surgery team about timing of the radiation treatment as well as the expected length of treatment
The goal is to reach a steady state as they are arming and positioning the radiation equipment so that the patient can be left alone for 5-10 minutes
As an extra precaution, you can connect a few extension tubings and thread that line into the shielded area in order to administer medication if needed
Position the monitors so that they can be seen from the shielded area, consider being able to see two monitors in case one fails

Emergence

Standard

Postoperative management

Disposition

Depends on patient and surgical factors, but usually stepdown, occasionally ICU or floor

Pain management

Depends on tumor location and size
For abdominal tumors, usually large incision, painful procedure
Neuraxial or regional pain control always, unless contraindicated
Multimodal pharmacologic pain control

Potential complications

IORT itself carries very low intraoperative and immediately postoperative complications
Most complications are related to the tumor resection itself
For large or vascular abdominal tumors concerns include:
- Aspiration
- IVC compression
- Hemorrhage due to bleeding of tumor or damage to surrounding vessels during resection
- Standard general anesthetic and operative complications

References

↑ ^1.0 ^1.1 Debenham, B. J., Hu, K. S., & Harrison, L. B. (2013). Present status and future directions of intraoperative radiotherapy. Lancet Oncology, 14(11), e457-64. doi:https://doi.org/10.1016/S1470-2045(13)70270-5
↑ Christopher G. Willett et al. Intraoperative Radiation Therapy. J Clin Oncol 25, 971-977(2007).DOI:10.1200/JCO.2006.10.0255
↑ Roth TM, Secord AA, Havrilesky LJ, et al. High dose rate intraoperative radiotherapy for recurrent cervical cancer and nodal disease. Gynecol Oncol. 2003;91:258–260. doi: 10.1016/s0090-8258(03)00443-8.
↑ Alfieri S, Morganti AG, Di Giorgio A, et al. Improved Survival and Local Control After Intraoperative Radiation Therapy and Postoperative Radiotherapy: A Multivariate Analysis of 46 Patients Undergoing Surgery for Pancreatic Head Cancer. Arch Surg. 2001;136(3):343–347. doi:10.1001/archsurg.136.3.343
↑ Moningi S, Armour EP, Terezakis SA, Efron JE, Gearhart SL, Bivalacqua TJ, Kumar R, Le Y, Kien Ng S, Wolfgang CL, Zellars RC, Ellsworth SG, Ahuja N, Herman JM. High-dose-rate intraoperative radiation therapy: the nuts and bolts of starting a program. J Contemp Brachytherapy. 2014 Mar;6(1):99-105. doi: 10.5114/jcb.2014.42027. Epub 2014 Apr 3. PMID: 24790628; PMCID: PMC4003434.

Top contributors: Ezekiel Egan

[:0-1] 1.0 ^1.1 Debenham, B. J., Hu, K. S., & Harrison, L. B. (2013). Present status and future directions of intraoperative radiotherapy. Lancet Oncology, 14(11), e457-64. doi:https://doi.org/10.1016/S1470-2045(13)70270-5

[2] Christopher G. Willett et al. Intraoperative Radiation Therapy. J Clin Oncol 25, 971-977(2007).DOI:10.1200/JCO.2006.10.0255

[3] Roth TM, Secord AA, Havrilesky LJ, et al. High dose rate intraoperative radiotherapy for recurrent cervical cancer and nodal disease. Gynecol Oncol. 2003;91:258–260. doi: 10.1016/s0090-8258(03)00443-8.

[4] Alfieri S, Morganti AG, Di Giorgio A, et al. Improved Survival and Local Control After Intraoperative Radiation Therapy and Postoperative Radiotherapy: A Multivariate Analysis of 46 Patients Undergoing Surgery for Pancreatic Head Cancer. Arch Surg. 2001;136(3):343–347. doi:10.1001/archsurg.136.3.343

[5] Moningi S, Armour EP, Terezakis SA, Efron JE, Gearhart SL, Bivalacqua TJ, Kumar R, Le Y, Kien Ng S, Wolfgang CL, Zellars RC, Ellsworth SG, Ahuja N, Herman JM. High-dose-rate intraoperative radiation therapy: the nuts and bolts of starting a program. J Contemp Brachytherapy. 2014 Mar;6(1):99-105. doi: 10.5114/jcb.2014.42027. Epub 2014 Apr 3. PMID: 24790628; PMCID: PMC4003434.

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