Division of Nursing, Midwifery and Social Work, School of Health Sciences, Faculty of Biology, Medicine and Health, University of Manchester, Manchester Academic Health Science Centre, Manchester, UK.
Division of Population Health, Health Services Research & Primary Care, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK.
Cochrane Database Syst Rev. 2021 May 10;5(5):CD013624. doi: 10.1002/14651858.CD013624.pub2.
Pressure ulcers (also known as pressure injuries, pressure sores, decubitus ulcers and bed sores) are localised injuries to the skin or underlying soft tissue, or both, caused by unrelieved pressure, shear or friction. Beds, overlays or mattresses are widely used with the aim of treating pressure ulcers.
To assess the effects of beds, overlays and mattresses on pressure ulcer healing in people with pressure ulcers of any stage, in any setting.
In November 2019, we searched the Cochrane Wounds Specialised Register; the Cochrane Central Register of Controlled Trials (CENTRAL); Ovid MEDLINE (including In-Process & Other Non-Indexed Citations); Ovid Embase and EBSCO CINAHL Plus. We also searched clinical trials registries for ongoing and unpublished studies, and scanned reference lists of relevant included studies as well as reviews, meta-analyses and health technology reports to identify additional studies. There were no restrictions with respect to language, date of publication or study setting.
We included randomised controlled trials that allocated participants of any age to pressure-redistributing beds, overlays or mattresses. Comparators were any beds, overlays or mattresses that were applied for treating pressure ulcers.
At least two review authors independently assessed studies using predetermined inclusion criteria. We carried out data extraction, 'Risk of bias' assessment using the Cochrane 'Risk of bias' tool, and the certainty of the evidence assessment according to Grading of Recommendations, Assessment, Development and Evaluations methodology.
We included 13 studies (972 participants) in the review. Most studies were small (median study sample size: 72 participants). The average age of participants ranged from 64.0 to 86.5 years (median: 82.7 years) and all studies recruited people with existing pressure ulcers (the baseline ulcer area size ranging from 4.2 to 18.6 cm,median 6.6 cm). Participants were recruited from acute care settings (six studies) and community and long-term care settings (seven studies). Of the 13 studies, three (224 participants) involved surfaces that were not well described and therefore could not be classified. Additionally, six (46.2%) of the 13 studies presented findings which were considered at high overall risk of bias. We synthesised data for four comparisons in the review: alternating pressure (active) air surfaces versus foam surfaces; reactive air surfaces versus foam surfaces; reactive water surfaces versus foam surfaces, and a comparison between two types of alternating pressure (active) air surfaces. We summarise key findings for these four comparisons below. (1) Alternating pressure (active) air surfaces versus foam surfaces: we are uncertain if there is a difference between alternating pressure (active) air surfaces and foam surfaces in the proportion of participants whose pressure ulcers completely healed (two studies with 132 participants; the reported risk ratio (RR) in one study was 0.97, 95% confidence interval (CI) 0.26 to 3.58). There is also uncertainty for the outcomes of patient comfort (one study with 83 participants) and adverse events (one study with 49 participants). These outcomes have very low-certainty evidence. Included studies did not report time to complete ulcer healing, health-related quality of life, or cost effectiveness. (2) Reactive air surfaces versus foam surfaces: it is uncertain if there is a difference in the proportion of participants with completely healed pressure ulcers between reactive air surfaces and foam surfaces (RR 1.32, 95% CI 0.96 to 1.80; I = 0%; 2 studies, 156 participants; low-certainty evidence). When time to complete pressure ulcer healing is considered using a hazard ratio, data from one small study (84 participants) suggests a greater hazard for complete ulcer healing on reactive air surfaces (hazard ratio 2.66, 95% CI 1.34 to 5.17; low-certainty evidence). These results are sensitive to the choice of outcome measure so should be interpreted as uncertain. We are also uncertain whether there is any difference between these surfaces in patient comfort responses (1 study, 72 participants; very low-certainty evidence) and in adverse events (2 studies, 156 participants; low-certainty evidence). There is low-certainty evidence that reactive air surfaces may cost an extra 26 US dollars for every ulcer-free day in the first year of use (1 study, 87 participants). Included studies did not report health-related quality of life. (3) Reactive water surfaces versus foam surfaces: it is uncertain if there is a difference between reactive water surfaces and foam surfaces in the proportion of participants with healed pressure ulcers (RR 1.07, 95% CI 0.70 to 1.63; 1 study, 101 participants) and in adverse events (1 study, 120 participants). All these have very low-certainty evidence. Included studies did not report time to complete ulcer healing, patient comfort, health-related quality of life, or cost effectiveness. (4) Comparison between two types of alternating pressure (active) air surfaces: it is uncertain if there is a difference between Nimbus and Pegasus alternating pressure (active) air surfaces in the proportion of participants with healed pressure ulcers, in patient comfort responses and in adverse events: each of these outcomes had four studies (256 participants) but very low-certainty evidence. Included studies did not report time to complete ulcer healing, health-related quality of life, or cost effectiveness.
AUTHORS' CONCLUSIONS: We are uncertain about the relative effects of most different pressure-redistributing surfaces for pressure ulcer healing (types directly compared are alternating pressure air surfaces versus foam surfaces, reactive air surfaces versus foam surfaces, reactive water surfaces versus foam surfaces, and Nimbus versus Pegasus alternating pressure (active) air surfaces). There is also uncertainty regarding the effects of these different surfaces on the outcomes of comfort and adverse events. However, people using reactive air surfaces may be more likely to have pressure ulcers completely healed than those using foam surfaces over 37.5 days' follow-up, and reactive air surfaces may cost more for each ulcer-free day than foam surfaces. Future research in this area could consider the evaluation of alternating pressure air surfaces versus foam surfaces as a high priority. Time-to-event outcomes, careful assessment of adverse events and trial-level cost-effectiveness evaluation should be considered in future studies. Further review using network meta-analysis will add to the findings reported here.
压疮(也称为压力性损伤、压力性溃疡、褥疮和床疮)是由于持续的压力、剪切力或摩擦力导致皮肤或皮下软组织局部损伤。床、衬垫或床垫被广泛用于治疗压疮。
评估各种阶段、各种环境下的压疮患者使用床、衬垫和床垫对压疮愈合的影响。
2019 年 11 月,我们检索了 Cochrane 伤口特化注册库、Cochrane 对照试验中心注册库(CENTRAL)、Ovid MEDLINE(包括正在进行和其他非索引引文)、Ovid Embase 和 EBSCO CINAHL Plus。我们还检索了正在进行和未发表研究的临床试验注册库,并对纳入的研究、综述、荟萃分析和卫生技术报告的参考文献进行了扫描,以确定其他研究。研究没有语言、出版日期或研究环境的限制。
我们纳入了将任何年龄的参与者随机分配到减压床、衬垫或床垫的随机对照试验。对照是用于治疗压疮的任何床、衬垫或床垫。
至少两名综述作者使用预定的纳入标准独立评估研究。我们进行了数据提取、使用 Cochrane“风险偏倚”工具进行“风险偏倚”评估,并根据推荐评估、制定和评估(GRADE)方法评估证据的确定性。
我们纳入了 13 项研究(972 名参与者)。大多数研究规模较小(中位数研究样本量:72 名参与者)。参与者的平均年龄为 64.0 岁至 86.5 岁(中位数:82.7 岁),所有研究均招募了现有压疮的参与者(基线溃疡面积从 4.2 厘米至 18.6 厘米,中位数为 6.6 厘米)。参与者来自急性护理环境(6 项研究)和社区和长期护理环境(7 项研究)。13 项研究中的 3 项(224 名参与者)涉及未详细描述的表面,因此无法分类。此外,13 项研究中有 6 项(46.2%)的结果被认为存在整体高风险偏倚。我们对综述中的四项比较进行了数据综合:交替压力(主动)空气表面与泡沫表面;反应性空气表面与泡沫表面;反应性水表面与泡沫表面,以及两种类型的交替压力(主动)空气表面之间的比较。我们在下面总结了这四项比较的关键发现。(1)交替压力(主动)空气表面与泡沫表面:我们不确定交替压力(主动)空气表面和泡沫表面在完全愈合的压疮比例方面是否存在差异(两项研究共 132 名参与者;一项研究报告的风险比(RR)为 0.97,95%置信区间(CI)为 0.26 至 3.58)。患者舒适度(一项研究 83 名参与者)和不良事件(一项研究 49 名参与者)的结果也存在不确定性。这些结果具有非常低的证据确定性。纳入的研究没有报告完全愈合溃疡的时间、健康相关生活质量或成本效益。(2)反应性空气表面与泡沫表面:我们不确定反应性空气表面和泡沫表面在完全愈合的压疮比例方面是否存在差异(RR 1.32,95%CI 0.96 至 1.80;I = 0%;2 项研究,156 名参与者;低确定性证据)。当使用风险比考虑完全压疮愈合时间时,来自一项小型研究(84 名参与者)的数据表明,反应性空气表面上完全愈合的风险更高(风险比 2.66,95%CI 1.34 至 5.17;低确定性证据)。这些结果对结局测量的选择敏感,因此应被解释为不确定。我们还不确定这些表面在患者舒适度反应(1 项研究,72 名参与者;非常低确定性证据)和不良事件(2 项研究,156 名参与者;低确定性证据)方面是否存在差异。反应性空气表面在第一年使用中每无溃疡日可能额外花费 26 美元(1 项研究,87 名参与者)。纳入的研究没有报告健康相关生活质量。(3)反应性水表面与泡沫表面:我们不确定反应性水表面和泡沫表面在愈合的压疮比例(RR 1.07,95%CI 0.70 至 1.63;1 项研究,101 名参与者)和不良事件(1 项研究,120 名参与者)方面是否存在差异。所有这些都具有非常低的证据确定性。纳入的研究没有报告完全愈合溃疡的时间、患者舒适度、健康相关生活质量或成本效益。(4)两种类型的交替压力(主动)空气表面之间的比较:我们不确定 Nimbus 和 Pegasus 交替压力(主动)空气表面在愈合的压疮比例、患者舒适度反应和不良事件方面是否存在差异:每个结局都有四项研究(256 名参与者),但证据确定性非常低。纳入的研究没有报告完全愈合溃疡的时间、健康相关生活质量或成本效益。
我们不确定大多数不同减压表面在压疮愈合方面的相对效果(直接比较的类型是交替压力空气表面与泡沫表面、反应性空气表面与泡沫表面、反应性水表面与泡沫表面以及 Nimbus 与 Pegasus 交替压力(主动)空气表面)。这些不同表面对舒适度和不良事件的影响也不确定。然而,与使用泡沫表面相比,使用反应性空气表面的人可能更有可能在 37.5 天的随访中完全治愈压疮,而反应性空气表面在无溃疡日的成本可能比泡沫表面高。未来在该领域的研究可以考虑将评估交替压力空气表面与泡沫表面作为一个高优先级。未来的研究应考虑时间到事件结局、仔细评估不良事件和试验级成本效益评估。进一步的综述使用网络荟萃分析将增加这里报告的发现。
