- Original Research
- Open Access
Can we make the basilic vein larger? maneuvers to facilitate ultrasound guided peripheral intravenous access: a prospective cross-sectional study
© Mahler et al; licensee Springer. 2011
Received: 28 June 2011
Accepted: 25 August 2011
Published: 25 August 2011
Studies have shown that vein size is an important predictor of successful ultrasound-guided vascular access. The objective of this study is to evaluate maneuvers designed to increase basilic vein size, which could be used to facilitate ultrasound-guided peripheral intravenous access (USGPIV) in the Emergency Department (ED) setting.
This was a prospective non-randomized trial. Healthy volunteers aged 18-65 were enrolled. Basilic veins were identified and the cross-sectional area measured sonographically. Following baseline measurement, the following maneuvers were performed: application of a tourniquet, inflation of a blood pressure (BP) cuff, application of a tourniquet with the arm lowered, and BP cuff inflation with the arm lowered. Following each maneuver there was 30 s of recovery time, and a baseline measurement was repeated to ensure that the vein had returned to baseline. Change in basilic vein size was modeled using mixed model analysis with a Tukey correction for multiple comparisons to determine if significant differences existed between different maneuvers.
Over the 5-month study period, 96 basilic veins were assessed from 52 volunteers. All of the maneuvers resulted in a statistically significant increase in basilic vein size from baseline (p < 0.001). BP cuff inflation had the greatest increase in vein size from baseline 17%, 0.87 mm 95% CI (0.70-1.04). BP cuff inflation statistically significantly increased vein size compared to tourniquet placement by 3%, 0.16 mm 95% CI (0.02-0.30).
The largest increase in basilic vein size was due to blood pressure cuff inflation. BP cuff inflation resulted in a statistically significant increase in vein size compared to tourniquet application, but this difference may not be clinically significant.
Intravenous (IV) access is often required in Emergency Department (ED) patients. Landmark techniques for obtaining peripheral IV access are usually successful, but patients with prior IV drug abuse, obesity, and chronic medical conditions are more likely to have failed attempts [1, 2]. Several studies have demonstrated that ultrasound can be used to successfully place peripheral IVs in patients who have failed landmark techniques [1, 3–6]. Prior to ultrasound-guided peripheral intravenous access (USGPIV), patients with failed landmark techniques often required central venous cannulation, a procedure with a higher complication rate and demanding more staff resources than peripheral access [2, 7].
Studies have shown that vein size is an important predictor of successful ultrasound-guided vascular access [8, 9]. While several studies have investigated maneuvers to increase femoral and jugular vein size to facilitate ultrasound-guided central line placement [10–14], few have evaluated maneuvers to increase basilic vein size. Studies evaluating basilic vein size have mainly focused on the creation of an AV fistula for dialysis rather than facilitating USGPIV [15–20]. The objective of this study is to evaluate maneuvers practical for ED use that could be utilized to improve the success of USGPIV by increasing basilic vein size.
This was a prospective non-randomized trial, which was approved by the Institutional Review Board of the sponsoring organization. Healthy volunteers aged 18-65 were enrolled over a 5-month period (January to May 2010) at Louisiana State University Health Sciences Center-Shreveport (LSUHSC-S). LSUHSC-S is a tertiary care facility, level one trauma center, and academic center home to a 3-year EM residency program training seven residents per year. Written informed consent was obtained from all volunteers. Volunteers were excluded from the study if they had any acute medical illness or were pregnant.
Volunteers were given a questionnaire to determine if they had undergone venopuncture or vascular access within the previous week, history of upper extremity thrombosis, history of humerus fracture, upper extremity deformity, or upper extremity surgery. If the subjects had any of the above in both arms they were excluded from the study. If the items in the questionnaire were present in only one arm, the volunteer was allowed to participate, but could only use the unaffected arm for the study measurements.
The basilic veins of each subject were identified using a high-frequency linear probe (8-12 MHz, L25 probe on a Sonosite M-Turbo or S-series, Sonosite, Inc., Bothell, WA, USA). After the basilic vein had been identified, two skin marks were made overlying the vein at a point of optimal vein visualization approximately 2-4 cm above the medial epicondyle. If a branching point off the basilic vein was identified within the 2-4 cm area, it was also used as a landmark. The skin marking and branch points were used to ensure that measurements of the vein during different maneuvers occurred at the same location.
The first measurement obtained was a baseline measurement in which subjects had their arms supported at the level of the heart. Following baseline measurement, the following maneuvers were performed: application of a tourniquet, inflation of a blood pressure cuff (above diastolic pressure), holding the arm below the level of the heart for more than 30 s prior to the application of a tourniquet, and holding the arm below the level of the heart for more than 30 s prior to inflation of a blood pressure cuff. Measurements of basilic vein size were made before and after each maneuver. Following each maneuver the subject was allowed at least 30 s of recovery time, and a baseline measurement was repeated to ensure that the vein had returned to its normal size (± 0.1 mm).
The effect of each maneuver on vein size was modeled using mixed model analysis. Tukey post hoc analysis was performed to determine if significant differences existed between different maneuvers and adjust for multiple comparisons. Covariance structure was determined by minimizing the AIC (Akaike information criterion), resulting in unstructured covariance. Statistical analysis was preformed with SAS 9.2 (Cary, NC) for Windows.
Over the 5-month study period from January to May 2010, 96 basilic veins were assessed from 52 volunteers. Of the 52 healthy volunteers, 44 had basilic veins measured in both arms, and 8 subjects had one basilic vein measured. The mean age of the volunteers was 25 (± SD 4 years), 14 (27%) were male, and 38 (73%) were female.
All pairwise comparisons of maneuvers used to dilate the basilic vein.
(A-B) Difference in
vein diameter (mm)
Adjusted 95% confidence interval of difference (mm)*
BP cuff below heart
Tourniquet below heart
Tourniquet below heart
Tourniquet below heart
BP cuff below heart
Tourniquet below heart
BP cuff below heart
BP cuff below heart
All of the maneuvers tested in our study resulted in a statistically significant increase in basilic vein size. Basilic vein size was increased the most by inflation of a blood pressure cuff above diastolic pressure with the arm supported at the level of the heart. The blood pressure cuff inflated with the arm resting below the heart resulted in the second largest increase in vein size. Blood pressure cuff inflation increased vein size more than a tourniquet or tourniquet applied with the arm below the level of the heart. However, the difference in vein size between BP cuff inflation and tourniquet application was small (3%, 0.16 mm). This difference would result in a change in cross-sectional area of only 5.5% (1.46 mm2), which may not be a clinically significant difference for clinicians attempting USGPIV.
Application of a tourniquet with the arm below the level of the heart was the least effective maneuver to increase vein size. On post hoc analysis this maneuver was statistically significantly inferior to all of the other maneuvers. In theory, lowering the arm below the level of the heart for 30 s should have resulted in venous pooling. Therefore, it was expected that the application of a tourniquet in this position would increase basilic vein size compared to a heart level arm postition. It was also expected that lowering the arm before inflation of a blood pressure cuff would increase basilic vein size compared to a blood pressure cuff used at the level of the heart, but this also did not occur. Another study enrolling healthy volunteers and dialysis patients also failed to show a significant difference in cephalic vein size following lowering of the arm and a combination of lowering the arm and warm water emersion .
It is unclear why lowering the arm seemed to have a negative impact on basilic vein size compared to the maneuvers performed at heart level. It is possible that despite ensuring that the vein returned to within ± 0.1 mm of its baseline diameter between different maneuvers, recovery time may have been inadequate. Furthermore, volunteers underwent each maneuver in an ordered fashion with maneuvers placing the arm at heart level performed before maneuvers placing the arm below the heart. It is possible that with each maneuver there was some attenuation in the ability of the vein to distend.
Our study differs from prior studies that have examined maneuvers to increase upper extremity vein size, which have mostly evaluated commercial devices or were designed to facilitate vein mapping for dialysis access rather than USGPIV [16, 18–20]. Nee et al. investigated antecubital fossa vein size for IV access with the application of a tourniquet versus a tourniquet used in combination with one of two commercially available devices, an Esmarch bandage and a Rhys-Davies exsanguinator. They determined that the combination of either device with a tourniquet was superior to a tourniquet alone . Another study evaluated a vacuum device used with a tourniquet to significantly increase vein size . Other studies have failed to demonstrate significant difference in vein sizes comparing different vein-dilating maneuvers including BP cuff inflation and tourniquets [16, 18]. In a study by Planken et al. on patients requiring dialysis access, no significant difference in vein size (cephalic) was found between a tourniquet and a graduated pressure cuff . It is unclear why our results differ from those of Planket et al., but it could be related to differences in the ability to distend veins in dialysis patients compared to healthy volunteers.
Several studies have also investigated maneuvers to increase femoral and jugular vein size to facilitate ultrasound-guided central line placement [10–14]. However, we are not aware of any prior studies investigating maneuvers with the aim of facilitating USGPIV. While USGPIV has a high success rate among patients who have failed landmark techniques, several studies have shown that vein size is an important predictor of successful ultrasound-guided vascular access [1, 3–6]. Therefore, maneuvers that can be practically implemented in the ED to increase basilic vein size may improve the success rate of USGPIV [1, 8, 9].
This study was performed on healthy volunteers, mostly young and female, rather than on patients requiring difficult IV access. Therefore, the results of this study may not be generalizable to patients requiring USGPIV. In addition, sonographic measurements were completed by two relatively inexperienced sonographers, and inter-observer reliability was not assessed. However, prior studies have shown that vein size measurements do not differ significantly between sonographers [18, 19].
Temperature changes are known to affect vein size, with warmer temperatures increasing vein size. Warm water emersion has been used as a technique to increased vein size [16, 20]. However, our study did not evaluate warm water emersion, because it did not seem practical in the ED setting. While temperature was not directly accounted for in this study, we do not believe that it functioned as a confounder since all of the subjects served as their own controls. Volunteers were present in the same climate-controlled environment throughout their exposure to the different maneuvers.
As previously mentioned, the decreased effectiveness of maneuvers completed with the arm resting below the level of the heart may have been the result of bias. Although procedures were utilized to ensure that the basilic vein returned to baseline size between different maneuvers, it is possible that our results were biased by inadequate recovery time. Also, sequence bias may have occurred, as the ability of veins to dilate may have been attenuated over time or with repetitive maneuvers. Future studies should have longer recovery periods and vary the sequence of the maneuvers studied.
In addition, some of the differences between maneuvers, while statistically significant, were small and may not be clinically significant. Furthermore, although prior studies have demonstrated that larger vein size improves USGPIV success, the subjects in this study were volunteers and did not have USGPIV performed. Therefore, further study is required to determine if specific maneuvers used for venous distention increase USGPIV success relative to other maneuvers.
All of the maneuvers tested resulted in a statistically significant increase in basilic vein size. Inflation of a blood pressure above diastolic pressure with the arm supported at the level of the heart produced the largest increase in basilic vein size. BP cuff inflation resulted in a statistically significant increase in vein size compared to tourniquet application, but this difference may not be clinically significant. The least effective maneuver was the application of a tourniquet with the arm resting below the level of the heart. Future investigation of these maneuvers designed to facilitate USGPIV should study patients with failed landmark IV techniques, have long recovery periods between maneuvers, and vary the sequence of the maneuvers studied.
Written informed consent was obtained from all study volunteers.
- Keyes LE, Frazee BW, Snoey ER, Simon BC, Christy D: Ultrasound-guided brachial and basilic vein cannulation in emergency department patients with difficult intravenous access. Ann Emerg Med 1999, 34(6):711–714. 10.1016/S0196-0644(99)70095-8View ArticlePubMedGoogle Scholar
- Chinnock B, Thornton S, Hendey GW: Predictors of success in nurse-performed ultrasound-guided cannulation. J Emerg Med 2007, 33(4):401–405. 10.1016/j.jemermed.2007.02.027View ArticlePubMedGoogle Scholar
- Mahler SA, Wang H, Lester C, Conrad SA: Ultrasound-guided peripheral intravenous access in the emergency department using a modified seldinger technique. J Emerg Med 2010, 39(3):325–9. 10.1016/j.jemermed.2009.02.013View ArticlePubMedGoogle Scholar
- Costantino TG, Kirtz JF, Satz WA: Ultrasound-guided peripheral venous access vs. the external jugular vein as the initial approach to the patient with difficult vascular access. J Emerg Med, in press.Google Scholar
- Brannam L, Blaivas M, Lyon M, Flake M: Emergency nurses' utilization of ultrasound guidance for placement of peripheral intravenous lines in difficult-access patients. Acad Emerg Med 2004, 11(12):1361–1363. 10.1111/j.1553-2712.2004.tb01929.xView ArticlePubMedGoogle Scholar
- Costantino TG, Parikh AK, Satz WA, Fojtik JP: Ultrasonography-guided peripheral intravenous access versus traditional approaches in patients with difficult intravenous access. Ann Emerg Med 2005, 46(5):456–461. 10.1016/j.annemergmed.2004.12.026View ArticlePubMedGoogle Scholar
- Steele R, Irvin CB: Central line mechanical complication rate in emergency medicine patients. Acad Emerg Med 2001, 8(2):204–207. 10.1111/j.1553-2712.2001.tb01292.xView ArticlePubMedGoogle Scholar
- Panebianco NL, Fredette JM, Szyld D, Sagalyn EB, Pines JM, Dean AJ: What you see (sonographically) is what you get: vein and patient characteristics associated with successful ultrasound-guided peripheral intravenous placement in patients with difficult access. Acad Emerg Med 2009, 16(12):1298–1303. 10.1111/j.1553-2712.2009.00520.xView ArticlePubMedGoogle Scholar
- Witting MD, Schenkel SM, Lawner BJ, Euerle BD: Effects of Vein Width and Depth on Ultrasound-guided Peripheral IV Success Rates. J Emerg Med 2010, 39(1):70–5. 10.1016/j.jemermed.2009.01.003View ArticlePubMedGoogle Scholar
- Fronek A, Criqui MH, Denenberg J, Langer RD: Common femoral vein dimensions and hemodynamics including Valsalva response as a function of sex, age, and ethnicity in a population study. J Vasc Surg 2001, 33(5):1050–1056. 10.1067/mva.2001.113496View ArticlePubMedGoogle Scholar
- Mallory DL, Shawker T, Evans RG, McGee WT, Brenner M, Parker M, Morrison G, Mohler P, Veremakis C, Parrillo JE: Effects of clinical maneuvers on sonographically determined internal jugular vein size during venous cannulation. Crit Care Med 1990, 18(11):1269–1273. 10.1097/00003246-199011000-00017View ArticlePubMedGoogle Scholar
- Rippey JC, Pascu O, Jacobs I: Abdominal compression effectively increases the size of the common femoral vein, as measured by ultrasonography. Ann Emerg Med 2008, 52(4):446–452. 10.1016/j.annemergmed.2008.04.022View ArticlePubMedGoogle Scholar
- Stone MB, Price DD, Anderson BS: Ultrasonographic investigation of the effect of reverse Trendelenburg on the cross-sectional area of the femoral vein. J Emerg Med 2006, 30(2):211–213. 10.1016/j.jemermed.2005.05.022View ArticlePubMedGoogle Scholar
- Verghese ST, Nath A, Zenger D Patel RI, Kaplan RF, Patel KM: The effects of the simulated Valsalva maneuver, liver compression, and/or Trendelenburg position on the cross-sectional area of the internal jugular vein in infants and young children. Anesth Analg 2002, 94(2):250–4.PubMedGoogle Scholar
- Hedges JR, Weinshenker E, Dirksing R: Evaluation of venous distension device: potential aid for intravenous cannulation. Ann Emerg Med 1986, 15(5):540–543. 10.1016/S0196-0644(86)80989-1View ArticlePubMedGoogle Scholar
- Korten E, Spronk S, Hoedt MT, et al.: Distensibility of forearm veins in haemodialysis patients on duplex ultrasound testing using three provocation methods. Eur J Vasc Endovasc Surg 2009, 38(3):375–380. 10.1016/j.ejvs.2009.03.029View ArticlePubMedGoogle Scholar
- Nee PA, Picton AJ, Ralston DR, Perks AG: Facilitation of peripheral intravenous access: an evaluation of two methods to augment venous filling. Ann Emerg Med 1994, 24(5):944–946. 10.1016/S0196-0644(94)70211-XView ArticlePubMedGoogle Scholar
- Planken RN, Keuter XH, Hoeks AP, Kooman JP, van der Sande FM, Kessels AG, Leiner T, Tordoir JH: Diameter measurements of the forearm cephalic vein prior to vascular access creation in end-stage renal disease patients: graduated pressure cuff versus tourniquet vessel dilatation. Nephrol Dial Transplant 2006, 21(3):802–806. 10.1093/ndt/gfi340View ArticlePubMedGoogle Scholar
- Planken RN, Keuter XH, Kessels AG, Hoeks AP, Leiner T, Tordoir JH: Forearm cephalic vein cross-sectional area changes at incremental congestion pressures: towards a standardized and reproducible vein mapping protocol. J Vasc Surg 2006, 44(2):353–358. 10.1016/j.jvs.2006.04.038View ArticlePubMedGoogle Scholar
- Van Bemmelen PS, Kelly P, Blebea J: Improvement in the visualization of superficial arm veins being evaluated for access and bypass. J Vasc Surg 2005, 42(5):957–962. 10.1016/j.jvs.2005.06.021View ArticlePubMedGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.