Temporary vascularization on ischemic limbs through arterial-medullar shunt: an experimental work

Poerschke, Ronaldo André; Silveira, Daniela Augustin; Lodi, Peterson; Titton, Wagner; Marx, Guilherme; Lampert, Alexandre Soares

doi:10.1590/S1677-54492012000100006

Abstracts

BACKGROUND: The authors idealized a temporary shunt between the femoral artery and the medullar canal on long bones to keep the viability of acutely ischemic limbs, while waiting for a definitive treatment. OBJECTIVE: To assess the flow on temporary shunts between the femoral artery and the marrow canal of the tibia during two hours in experimental dogs, which had the femoral artery interrupted. METHODS: Two groups with three dogs on the Control Group and six on the Intervention Group were allocated at random. The controls had the right femoral common artery interrupted. The Intervention Group received a shunt between the iliac external artery and the medullar canal of the right tibia in addition. After two hours, the measure of the pH, blood coloration, blood flow in sonar Doppler on the ischemic limbs were performed. The lungs were withdrawn in thoracic block for anatomic-pathologic analyses. RESULTS: The capillary blood pH average of the limb extremities in the Control Group was 6.97 (±0.39) and in the Intervention Group was 7.25 (±0.46), with p<0.001, and the blood coloration in the Intervention Group kept the bright aspect in all animals. The shunts needed in average three irrigations with saline heparin solution to be kept unobstructed. The macroscopic and microscopic evaluation of the pulmonary tissue did not evidence fat emboli. CONCLUSION: The artery osseous or artery medullar (marrow) shunt showed to be feasible on the technical point of view in the laboratory.

vascular grafting; limb salvage; ischemia

CONTEXTO: Os autores idealizaram um shunt temporário entre a artéria femoral e o canal medular de ossos longos para manter a viabilidade dos membros agudamente isquêmicos, enquanto não é possível estabelecer um tratamento definitivo. OBJETIVO: Avaliar a perviedade de shunts temporários arteriomedulares e a perfusão dos membros, durante duas horas em cães de experimentação, que tiveram a artéria femoral ligada. MÉTODOS: Alocaram-se aleatoriamente dois grupos, com três cães no Grupo Controle e seis no Grupo Intervenção. Os controles tiveram a artéria femoral comum direita ligada. O Grupo Intervenção, além da ligadura da artéria, recebeu um shunt. Após duas horas, realizou-se a medida de pH dos membros isquêmicos; avaliação do fluxo arterial por meio de um sonar Doppler; avaliação da coloração do sangramento na extremidade distal do membro e foram retirados em bloco torácico os pulmões para análise anatomopatológica. RESULTADOS: A média do pH do sangue capilar das extremidades do membros no Grupo Controle foi de 6,97 (±0,39); no Grupo Intervenção o pH foi de 7,25 (±0,46), com p<0,001; a coloração do sangue no Grupo Intervenção manteve-se com aspecto rutilante em todos os animais. Os shunts necessitaram, em média, três irrigações com solução salina heparinada para manterem-se pérvios. A avaliação macroscópica e microscópica do tecido pulmonar não evidenciou embolia gordurosa. CONCLUSÃO: O shunt arterio-osteal ou arteriomedular apresentou viabilidade técnica em laboratório.

enxerto vascular; salvamento de membro; isquemia

ORIGINAL ARTICLE

Temporary vascularization on ischemic limbs through arterial-medullar shunt: an experimental work*

Ronaldo André Poerschke^I; Daniela Augustin Silveira^II; Peterson Lodi^III; Wagner Titton^III; Guilherme Marx^III; Alexandre Soares Lampert^III

^IVascular and Endovascular Surgeon; MSc in Medical Sciences; Professor of Anatomy at the Medical School of UPF Passo Fundo (RS), Brazil.

^IIProfessor of Patology at the Medical School of UPF Passo Fundo (RS), Brazil.

^IIIMedical Students at UPF Passo Fundo (RS), Brazil.

Correspondence to

ABSTRACT

BACKGROUND: The authors idealized a temporary shunt between the femoral artery and the medullar canal on long bones to keep the viability of acutely ischemic limbs, while waiting for a definitive treatment.

OBJECTIVE: To assess the flow on temporary shunts between the femoral artery and the marrow canal of the tibia during two hours in experimental dogs, which had the femoral artery interrupted.

METHODS: Two groups with three dogs on the Control Group and six on the Intervention Group were allocated at random. The controls had the right femoral common artery interrupted. The Intervention Group received a shunt between the iliac external artery and the medullar canal of the right tibia in addition. After two hours, the measure of the pH, blood coloration, blood flow in sonar Doppler on the ischemic limbs were performed. The lungs were withdrawn in thoracic block for anatomic-pathologic analyses.

RESULTS: The capillary blood pH average of the limb extremities in the Control Group was 6.97 (±0.39) and in the Intervention Group was 7.25 (±0.46), with p<0.001, and the blood coloration in the Intervention Group kept the bright aspect in all animals. The shunts needed in average three irrigations with saline heparin solution to be kept unobstructed. The macroscopic and microscopic evaluation of the pulmonary tissue did not evidence fat emboli.

CONCLUSION: The artery osseous or artery medullar (marrow) shunt showed to be feasible on the technical point of view in the laboratory.

Keywords: vascular grafting; limb salvage; ischemia.

Introduction

There are situations in which early vascular interventions are not possible either due to the geographical distance to transport the victim to a specialized medical center or due to the patient's critical condition. The authors have designed a temporary shunt to maintain perfusion of ischemic limbs.

Inspired by the techniques of fluid infusion through an intraosseous vascular access^1,2 used in Emergency Rooms³, we formulated the hypothesis that an iliac-medullary shunt could maintain limbs viable in case of acute arterial occlusion until the definitive treatment were instituted. To test this hypothesis, we carried out an experiment with dogs.

Methods

The experiment was made in compliance with the Colégio Brasileiro de Experimentação Animal e Sociedade Brasileira de Ciência de Animais de Laboratório (COBEA/SBCAL), and approved by the Ethics Committee, linked to the National Ethics Committee in research (protocol from the Animal Studies Ethics Committee [CEUA] from Universidade de Passo Fundo 00001/2010). All animal experiments were performed under general anesthesia, with additional analgesia. Pre-anesthesia consisted of intramuscular (IM) morphine 1.0 mg/kg 20 minutes before the procedure. The use of Fentanyl was limited to analgesic rescue, if necessary. Anesthesia maintenance was: thiopental 5 mg/kg to keep the animal relaxed, with readministration if necessary; fentanyl 15 µg/kg every 40 minutes. The airway was secured with an orotracheal tube, and ventilation was maintained with Aire and O2 at 3 L/min. Nine adult dogs (undefined type) were randomly divided into two groups: the Control Group, with three dogs, and the Intervention Group, with six dogs.

In both groups, basal measurements of arterial blood gasometry (assessed by radiometer ABL 555, USA) and invasive blood pressure measurements were performed, at the beginning and in the end of each experiment.. In the Control Group dogs, the right common femoral artery was ligated at the inguinal crease through a small transversel incision. The dogs were given endovenous heparin in the dose of 100 U/kg. Two hours later, capillary blood was collected, and bleeding from a wound at the paw of the ischemic limb was observed. The animals were then euthanized with sodium thiopental

(50 mg/kg) and, five minutes later, intravenous potassium chloride (4 mg/kg), and their lungs were removed.

In the Intervention Group, the dogs had their right common femoral arteries ligated at the inguinal region through a transverse incision. They were then given heparin 100 U/kg and a shunt between the right iliac artery and the medullary cavity of the right tibia was performed. In order to perform the temporary shunt, a small pretibial incision was made, followed by exposition of the superior third of the tibia. The bone was then perforated with a 4.5 mm drill through the medullary cavity. A plastic cannula was attached to the orifice (Figure 1). Just proximal to the common femoral artery ligature, a 5F catheter was introduced (Figure 1). The system of irrigation was then connected to the cannula, thus establishing the shunt cycle (Figure 1).

Patency of the system was measured every 15 minutes using Doppler ultrasonography 10 Mhz (Microen, Brazil). This method was also used to evaluate arterial flow in the ischemic limbs. When occlusion of the system was observed, irrigation with heparin saline solution was performed (1,000 mL/1 mL) until it was solved.

After two hours, blood from the bleeding of the lower ischemic limb was collected for pH measurement and color assessment. Complete gasometric analysis could not be performed because the volume of blood collected from the animal's paw was not adequate.

The animals were euthanized using the same procedures listed for Control Group, including the removal of the lungs for anatomopathological analysis. The organs were embedded in formaldehyde 10% and sectioned for macroscopic analysis. Ten samples of the pulmonary parenchyma were randomly collected by a blinded pathologist. These samples were submitted to the routine histological procedures (Hematoxylin Eosin staining) and to optical microscopy (100 and 400 X) assessment, also performed by a blinded pathologist.

To process these data, the authors used the SPSS 15.0 program and obtained mean values, as well as standard errors and deviations.

Results

The characteristics of the individuals of groups did not differ (Table 1). Mean weight was 9.8 kg (±1.8) in the Control Group and 10.5 kg (±3.5) in the Intervention Group. Mean invasive blood pressure was 88.6 mmHg (±12.6) in the Control Group and 91.8 mmHg (±22) in the Intervention Group.

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The pH of the sample collected from the femoral artery before ligation (pre-intervention) was 7.34 (±0.005) in the Control Group, and 7.33 (±0.005) in the Intervention Group. Initial O2 saturation was 90.6% (±1.4) in the Control Group, and 90.3% (±1.3) in the Intervention Group. The animals remained hemodynamically stable during the procedure.

The shunts presented an average of three occlusions in two hours, but blood flow could be reestablished by irrigating the system with heparin solution (about 10 to 15 mL).

Doppler ultrasonography showed monophasic flow in the distal arteries of the limbs that received shunt.

The blood color from the ischemic limbs after two hours of the experiment in the Control Group animals was violet and dark, while in the animals from the Intervention Group it was bright red.

Mean capillary blood pH of the ischemic extremity was 6.97 (±0.39) in the Control Group, and 7.25 (±0.46) in the Intervention Group, with p<0.001 (Table 2 e Graph 1).

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The anatomopathological analysis of the pulmonary parenchyma showed areas of atelectasia and discrete intra-alveolar edema. Neither areas of parenchyma infarction nor intravascular fat emboli were identified, although such emboli could present as cholesterol crystal or intravascular vacuoles (Figures 2 and 3).

Discussion

The temporary shunt was shown to be technically feasible. Shunt occlusions occurred on average three times in two hours of experiment, and could be easily solved by irrigation. This method allowed for partial perfusion of the limb, which was confirmed by tissue pH value, by Doppler flow ultrasonography, and by observing blood color. Lung tissue microscopic analysis showed areas of intra-alveolar edema and atelectasia probably due to respiratory distress, an event observed in both groups, besides the fact that the animals were under anesthesia for four to six hours.

The shunt allows arterial blood flow into the marrow interstitial cavity, which penetrates the vascular space through the marrow sinusoids⁴. The vascularization of the cortical layer in long bone diaphyses occurs from the marrow to the cortical; the feeding arteries penetrate the marrow, give origin to the longitudinal arteries which, on its turn, give origin to the vessels for the cortical layer of the bone^4-7. The adjacent tissues receive the perfusion through the anastomosis with the periosteum.

Intraosseous access is widely used for emergency treatment in children and adults³, and over 100 drugs and solutions have been reported to be administered by this means⁸. Complications are rare. Fat emboli is a particularly worrisome event because it may cause fat embolism syndrome, that may result in lung and brain damage^9,10. Fat embolism was not detected by macroscopic and microscopic evaluations, and is a rare complication related to intraosseous infusion of crystalloid solutions³. The fat embolism syndrome is often associated with long bone fractures and bone tissue manipulation, and is caused by the marrow veins' rupture^9-11.

The study initially focused on the technical success of shunting between a great caliber artery and the marrow cavity of a long bone, and, technically, it was proved to be feasible.

References

1. Drinker CK, Drinker KR, Lund CC. The circulation in the mammalian bone marrow. Am J Physiol. 1922;62:1-92.
2. Josefson A. A new method of treatamet intraosseal injections. Acta Med Scand. 1934;81:550-84.
3. Lane JC, Guimarães HP. Acesso venoso intra-óssea em urgências médicas. Rev Bras Terapia Int. 2008;20(1):4-10.
4. Williams W, Dyson B. Gray Anatomia. São Paulo: Guanabara Koogan; 1995.
5. Latarjet M, Riard AR. Anatomia Humana. 3a. ed. Madri: Editora Panamericana; 1999.
6. Pazzaglia UE, Congiu T, Raspanti M, Ranchetti F, Quacci D. Anatomy of the intracortical canal system: scanning electron microscopy study in rabbit femur. Clin Orthop Relat Res. 2009;467:2446-56.
7. Pazzaglia UE, Congiu T, Ranchetti F, Salari M, Dell'Orbo C. Scanning electron microscopy study of bone intracortical vessels using an injection and fractured surfaces technique. Anat Sci Int. 2010;85:31-7.
8. Dubick MA, Holcomb JB. A review of intraosseus vascular access: current status and military application. Mil Med. 2000;165:552-9.
9. De Araújo CAF, Rocha MA, Taia C, Silva LC. Síndrome de embolia gordurosa. Rev Bras Ortop. 1997;32:909-12.
10. Filomeno LTB, Carelli CR, Da Silva NC, De Barros Filho TEP, Amatuzzi MM. Embolia gordurosa: Uma revisão para a prática ortopédica atual. Acta Ortopédica Bras. 2005;13(4):196-208.
11. Corsi PR, Gianini JA, Rasllan S. Embolia gordurosa pós-traumática: revisão da literatura. Acta Cir Bras. 1993;8(3):134-40.

Correspondência

Ronaldo André Poerschke

Rua Princesa Isabel, 128

CEP 99050-100 Passo Fundo (RS), Brasil

E-mail:

poerschke@upf.br

Publication Dates

Publication in this collection
25 Oct 2012
Date of issue
Mar 2012

History

Received
03 Aug 2011
Accepted
07 Nov 2011

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Drinker CK, Drinker KR, Lund CC. The circulation in the mammalian bone marrow. Am J Physiol. 1922;62:1-92.

[2] 2. Josefson A. A new method of treatamet intraosseal injections. Acta Med Scand. 1934;81:550-84.

[3] 3. Lane JC, Guimarães HP. Acesso venoso intra-óssea em urgências médicas. Rev Bras Terapia Int. 2008;20(1):4-10.

[4] 4. Williams W, Dyson B. Gray Anatomia. São Paulo: Guanabara Koogan; 1995.

[5] 5. Latarjet M, Riard AR. Anatomia Humana. 3a. ed. Madri: Editora Panamericana; 1999.

[6] 6. Pazzaglia UE, Congiu T, Raspanti M, Ranchetti F, Quacci D. Anatomy of the intracortical canal system: scanning electron microscopy study in rabbit femur. Clin Orthop Relat Res. 2009;467:2446-56.

[7] 7. Pazzaglia UE, Congiu T, Ranchetti F, Salari M, Dell'Orbo C. Scanning electron microscopy study of bone intracortical vessels using an injection and fractured surfaces technique. Anat Sci Int. 2010;85:31-7.

[8] 8. Dubick MA, Holcomb JB. A review of intraosseus vascular access: current status and military application. Mil Med. 2000;165:552-9.

[9] 9. De Araújo CAF, Rocha MA, Taia C, Silva LC. Síndrome de embolia gordurosa. Rev Bras Ortop. 1997;32:909-12.

[10] 10. Filomeno LTB, Carelli CR, Da Silva NC, De Barros Filho TEP, Amatuzzi MM. Embolia gordurosa: Uma revisão para a prática ortopédica atual. Acta Ortopédica Bras. 2005;13(4):196-208.

[11] 11. Corsi PR, Gianini JA, Rasllan S. Embolia gordurosa pós-traumática: revisão da literatura. Acta Cir Bras. 1993;8(3):134-40.