Selective Percutaneous Desiccation of the Perforators with Radiofrequency for Strategic Transfer of Angiosomes in a Sequential Four-Territory Cutaneous Island Flap Model

Delineating the vascular territory (perforasome) of a perforator in the lower extremity of the rabbit with four-dimensional computed tomographic angiography

BACKGROUND

The anatomy of any particular vascular perforator relative to its vascular territory (perforasome) and flow characteristics is unique and complex. This arterial perforasome study with laboratory rabbits was conducted to assess four-dimensional computed tomographic angiography as an imaging tool for the design of individualized tissue transfers. This study offers clinically relevant information that should improve flap survival.

METHODS

Six New Zealand White rabbits weighing 3.0 to 3.25 kg underwent contrast-enhanced four-dimensional computed tomographic angiography in a 128-slice scanner after intraarterial injection of iopromide iodinated contrast material. Based on the image data, the perforasome of the posterior thigh perforator was marked onto the posterior thigh skin. The perforasome size was confirmed by microangiography. Data from four-dimensional computed tomographic angiography and microangiography were statistically compared.

RESULTS

Four-dimensional computed tomographic angiography clearly and accurately delineated the perfusion and vascular territories of the perforators. The area of the perforator flap as measured with four-dimensional computed tomographic angiography compared favorably to that obtained by means of microangiography; there was no statistically significant difference in the results from the two methods.

CONCLUSIONS

This study demonstrated that four-dimensional computed tomographic angiography was capable of accurately characterizing the vascular territory and flow characteristics of the arterial perforator in live rabbits. This technique for determining perforator location, axiality, and optimal perfusion territory will potentially benefit human patients.

The effect of "minimally invasive transfer of angiosomes" on vascularization of prefabricated/prelaminated tissues

Prefabrication and prelamination are experimental and clinical applications of reconstructive surgery and inspired the vascularization challenge of engineered tissues. The purpose of this study is to test the efficiency of "minimally invasive transfer of angiosomes" to enhance the vascularization of the final construct during prefabrication and prelamination. Fifteen rabbits were used for this study. Three of the animals were used in a pilot study to develop the protocol. During the study, thoracodorsal and lateral thoracic vascular pedicles on each side constituted 4 study groups. The pedicles were prepared to simulate prelamination with and without transfer of angiosomes, and prefabrication with and without transfer of angiosomes. In all of the groups, a 10 x 15 mm auricular cartilage graft was used as the construct to be vascularized. After 2 weeks, vascularization of the grafts was evaluated by means of microangiography and histology. Results indicate that both prelamination and prefabrication with transfer of angiosomes displayed better vascularization, both qualitatively and quantitatively. However, prelamination with transfer of angiosomes group displayed distinct statistical superiority. The results suggest that minimally invasive transfer of angiosomes coupled with the procedure significantly increases the induction of angiogenesis during prelamination and prefabrication.

Comparison of two different vascular delay methods in a rat cranial epigastric perforator flap model

The effectiveness of vascular delay in transverse rectus abdominis muscle flaps has been demonstrated in many studies. In deep inferior epigastric perforator flaps, however, the effectiveness of ligation of deep versus superficial epigastric vessels in producing delay is unclear. Using a rat model, we compared ligation of deep and superficial vessels with each other and with a (nondelayed) control group (n = 10). One vascular delay group (n = 10) had ligation of the contralateral cranial epigastric vessels (homolog to the human deep inferior epigastric vessels); the other (n = 10) had ligation of contralateral superficial inferior epigastric vessels. One week later, cranial epigastric perforator flap elevation was performed. Both vascular techniques were effective in producing delay, and there was no statistically significant difference between the 2 groups. Ligation of superficial inferior epigastric vessels, deep inferior epigastric vessels, or both, at least 1 week prior to the deep inferior epigastric perforator flap elevation may increase the usable skin paddle area in humans.