ABSTRACT
With the recent revision of mammography screening guidelines, more women are diagnosed
with breast carcinoma and are undergoing mastectomies than ever before. Following
these procedures, women often choose to undergo breast reconstruction for restoration
of their self-image and sense of wholeness. The demand for such restoration has fueled
research and development of newer techniques.
Through its evolution, breast reconstruction has included several modalities. Most
common are those techniques utilizing silicone and saline implants. Implants are advantageous
because they are simple to insert and relatively safe. They also do not require a
donor site with its resulting scars. However, they frequently require expansion of
the overlying skin and subsequent replacement of the expanders with permanent implants.
Expanders are limited where large amounts of skin need to be recruited compared with
autogenous reconstruction. Implants are largely incompatible with radiation therapy
whether it is performed pre- or postoperatively. They often lack ptosis, making them
appear less natural than the normal breast. This may require manipulation of the other
breast for symmetry even when size is acceptable. A failure rate of 2% per year1 and contracture development necessitating implant replacement or removal and capsulectomy
may cause implants to become more expensive than other techniques over the long term.2
These disadvantages have helped foster the evolution of alternative reconstructive
techniques over the last decade. Research and development have now given way to newer
microvascular techniques, including transverse rectus abdominis myocutaneous (TRAM)
flaps. This class of autogenous breast reconstruction has certain advantages over
implant-based reconstruction. The reconstructed breast mound itself is made of muscle,
fat and skin, ingredients that provide warmth, softness, and a consistency very similar
to that of a natural breast.3 As with any procedure, there are disadvantages. Common to all autogenous breast reconstruction
is a longer initial surgical procedure. Additionally, TRAM flaps may be associated
with abdominal hernias and restricted range of motion.4
A newer procedure that is done in increasing numbers is the perforator artery flap.
Koshima and Soeda first described paraumbilical perforator flaps in 1989.5 This technique involves the harvesting of free flaps based on dissection of the myocutaneous
perforators, using fat and skin alone, and avoiding muscle sacrifice. These perforator
flaps can be based on the deep inferior epigastric perforator (DIEP), the thoracodorsal
artery perforator, the lateral femoral circumflex artery perforator, and the gluteal
artery perforators.6 Allen and Treece first introduced perforator flaps for breast reconstruction.7
Approximately 700 perforator flaps for breast reconstruction have been successfully
performed at the Louisiana State University Medical Center (LSUMC) since 1992. In
this series, there were few donor site complications with perforator flaps when compared
with TRAM flaps. Most notable was a decrease in the number of abdominal hernias and
muscle weakness. Additionally, mesh is avoided, even in bilateral cases. There tends
to be diminished postoperative pain and a shortened hospital stay which results in
cost savings.8
Another major advantage of not including muscle with these flaps is that the vessel
that courses through is dissected out and becomes part of the pedicle. This at least
doubles the usable length of the pedicle, making anastomosis easier.
Initially there was concern that breast reconstruction using a perforator flap would
lead to a longer operative procedure and increased cost. However, the perforator flap
has been shown, on average, to cost less and take less time to perform than the TRAM
flap.2,8
Donor sites illustrated in this article include the lower abdomen, the lateral thigh,
the back, and the upper and lower buttock.
Keywords
Breast reconstruction - breast cancer - perforator - free flap
