OBJECTIVES: The choice of programmable or nonprogrammable shunts for the management of hydrocephalus after aneurysmal subarachnoid hemorrhage (SAH) remains undefined. Variable intracranial pressures make optimal management difficult. Programmable shunts have been shown to reduce problems with drainage, but at 3 times the cost of nonprogrammable shunts. METHODS: All patients who underwent insertion of a ventriculoperitoneal shunt for hydrocephalus after aneurysmal SAH between 2006 and 2012 were included. Patients were divided into those in whom nonprogrammable shunts and those in whom programmable shunts were inserted. The rates of shunt revisions, the reasons for adjustments of shunt settings in patients with programmable devices, and the effectiveness of the adjustments were analyzed. A cost-benefit analysis was also conducted to determine if the overall cost for programmable shunts was more than for nonprogrammable shunts. RESULTS: Ninety-four patients underwent insertion of shunts for hydrocephalus secondary to SAH. In 37 of these patients, nonprogrammable shunts were inserted, whereas in 57 programmable shunts were inserted. Four (7%) of 57 patients with programmable devices underwent shunt revision, whereas 8 (21.6%) of 37 patients with nonprogrammable shunts underwent shunt revision (p = 0.0413), and 4 of these patients had programmable shunts inserted during shunt revision. In 33 of 57 patients with programmable shunts, adjustments were made. The adjustments were for a trial of functional improvement (n = 21), overdrainage (n = 5), underdrainage (n = 6), or overly sunken skull defect (n = 1). Of these 33 patients, 24 showed neurological improvements (p = 0.012). Cost-benefit analysis showed $646.60 savings (US dollars) per patient if programmable shunts were used, because the cost of shunt revision is a lot higher than the cost of the shunt. CONCLUSIONS: The rate of shunt revision is lower in patients with programmable devices, and these are therefore more cost-effective. In addition, the shunt adjustments made for patients with programmable devices also resulted in better neurological outcomes.
OBJECTIVES: The choice of programmable or nonprogrammable shunts for the management of hydrocephalus after aneurysmal subarachnoid hemorrhage (SAH) remains undefined. Variable intracranial pressures make optimal management difficult. Programmable shunts have been shown to reduce problems with drainage, but at 3 times the cost of nonprogrammable shunts. METHODS: All patients who underwent insertion of a ventriculoperitoneal shunt for hydrocephalus after aneurysmalSAH between 2006 and 2012 were included. Patients were divided into those in whom nonprogrammable shunts and those in whom programmable shunts were inserted. The rates of shunt revisions, the reasons for adjustments of shunt settings in patients with programmable devices, and the effectiveness of the adjustments were analyzed. A cost-benefit analysis was also conducted to determine if the overall cost for programmable shunts was more than for nonprogrammable shunts. RESULTS: Ninety-four patients underwent insertion of shunts for hydrocephalus secondary to SAH. In 37 of these patients, nonprogrammable shunts were inserted, whereas in 57 programmable shunts were inserted. Four (7%) of 57 patients with programmable devices underwent shunt revision, whereas 8 (21.6%) of 37 patients with nonprogrammable shunts underwent shunt revision (p = 0.0413), and 4 of these patients had programmable shunts inserted during shunt revision. In 33 of 57 patients with programmable shunts, adjustments were made. The adjustments were for a trial of functional improvement (n = 21), overdrainage (n = 5), underdrainage (n = 6), or overly sunken skull defect (n = 1). Of these 33 patients, 24 showed neurological improvements (p = 0.012). Cost-benefit analysis showed $646.60 savings (US dollars) per patient if programmable shunts were used, because the cost of shunt revision is a lot higher than the cost of the shunt. CONCLUSIONS: The rate of shunt revision is lower in patients with programmable devices, and these are therefore more cost-effective. In addition, the shunt adjustments made for patients with programmable devices also resulted in better neurological outcomes.
Authors: Syed M Adil; Beiyu Liu; Lefko T Charalambous; Musa Kiyani; Robert Gramer; Christa B Swisher; Laura Zitella Verbick; Aaron McCabe; Beth A Parente; Promila Pagadala; Shivanand P Lad Journal: Transl Stroke Res Date: 2019-03-13 Impact factor: 6.829
Authors: Virendra Rajendrakumar Desai; Saeed Sam Sadrameli; Amanda V Jenson; Samuel K Asante; Bradley Daniels; Todd W Trask; Gavin Britz Journal: Surg Neurol Int Date: 2020-09-05
Authors: Sebastian Arts; Jasper Hans van Lieshout; Martine van Bilsen; Cihat Karadag; Thomas Beez; Leonie van den Abbeele; Rene Aquarius; Saman Vinke; Ronald H M A Bartels; Erik J van Lindert; Daniel Hänggi; Hieronymus D Boogaarts Journal: Acta Neurochir (Wien) Date: 2022-09-23 Impact factor: 2.816
Authors: Eng Tah Goh; Christine Lock; Audrey Jia Luan Tan; Bee Ling Tan; Sai Liang; Robin Pillay; Sumeet Kumar; Azlina Ahmad-Annuar; Vairavan Narayanan; Janell Kwok; Yi Jayne Tan; Adeline Sl Ng; Eng King Tan; Zofia Czosnyka; Marek Czosnyka; John D Pickard; Nicole C Keong Journal: Front Neurol Date: 2022-07-12 Impact factor: 4.086