Zusammenfassung
In diesem Kapitel werden die wichtigsten zukunftsweisenden Entwicklungen im Rahmen der Weaningforschung und -praxis aufgeführt. Hierzu zählen telemedizinische Entwicklungen und Entwicklungen in der außerklinischen Beatmung.
Literatur zu Abschnitt 8.1
- [1]
- [2]Masefield S, Vitacca M, Dreher M, Kampelmacher M, Escarrabill J, Paneroni M, Powell P, Ambrosino N (2017) Attitudes and preferences of home mechanical ventilation users from four European countries: an ERS/ELF survey. ERJ Open Res 3(2)CrossRefGoogle Scholar
- [3]Fernández-Granero MA, Sánchez-Morillo D, León-Jiménez A, Crespo LF (2014) Automatic prediction of chronic obstructive pulmonary disease exacerbations through home telemonitoring of symptoms. Biomed Mater Eng 24(6):3825–3832PubMedGoogle Scholar
- [4]Chatwin M, Hawkins G, Panicchia L, Woods A, Hanak A, Lucas R, Baker E, Ramhamdany E, Mann B, Riley J, Cowie MR, Simonds AK (2016) Randomised crossover trial of telemonitoring in chronic respiratory patients (TeleCRAFT trial). Thorax 71(4):305–311CrossRefPubMedPubMedCentralGoogle Scholar
- [5]Vitacca M, Bianchi L, Guerra A, Fracchia C, Spanevello A, Balbi B, Scalvini S (2009) Tele-assistance in chronic respiratory failure patients: a randomised clinical trial. Eur Respir J 33(2):411–418CrossRefPubMedGoogle Scholar
- [6]Deutsche Gesellschaft für Pneumologie und Beatmungsmedizin e. V. S2k – Leitlinie Nichtinvasive und invasive Beatmung als Therapie der chronischen respiratorischen Insuffizienz, Revision 2017. http://www.awmf.org/uploads/tx_szleitlinien/020-008l_S2k_NIV_Nichtinvasive_invasive_Beatumung_Insuffizienz_2017-07.pdf
Literatur zu Abschnitt 8.2
- [7]Polar P (2018) 90440 Kempele, Finland. https://flow.polar.com
- [8]Strava Netzwerk. https://www.strava.com/?hl=de
- [9]Airview Patientenmanagementsystem (2018) https://www.resmed.com/de-de/commercial-partner/products/monitoring-and-data-management/airview-patient-management-system.html
- [10]Storre JH, Dellweg D (2014) Monitoring of patients receiving mechanical ventilation. Pneumologie 68(8):532–541. https://doi.org/10.1055/s-0034-1365742
- [11]Grabar E (2015) Unter Kontrolle. Sueddeutsche Zeitung 12 Dez.:38–39Google Scholar
- [12]Overbeck P (2015) Herzinsuffizienz: Implantierter Drucksensor erspart die Klinik. Ärzte Zeitung Dez.:1Google Scholar
- [13]Ambrogio C, Lowman X, Kuo M et al (2009) Sleep and non-invasive ventilation in patients with chronic respiratory insufficiency. Intensive Care Med 35(2):306–313. https://doi.org/10.1007/s00134-008-1276-4
- [14]Briones Claudett KH, Briones Claudett M, Chung Sang Wong M, Nuques Martinez A, Soto Espinoza R, Montalvo M et al (2013) Noninvasive mechanical ventilation with average volume assured pressure support (AVAPS) in patients with chronic obstructive pulmonary disease and hypercapnic encephalopathy. BMC Pulm Med 13:12CrossRefPubMedPubMedCentralGoogle Scholar
- [15]Crisafulli E, Manni G, Kidonias M, Trianni L, Clini EM (2009) Subjective sleep quality during average volume assured pressure support (AVAPS) ventilation in patients with hypercapnic COPD: a physiological pilot study. Lung 187(5):299–305CrossRefPubMedGoogle Scholar
- [16]Ekkernkamp E, Kabitz HJ, Walker DJ, Schmoor C, Storre JH, Windisch W, Dreher M (2014) Minute ventilation during spontaneous breathing, high-intensity noninvasive positive pressure ventilation and intelligent volume assured pressure support in hypercapnic COPD. COPD 11(1):52–58CrossRefPubMedGoogle Scholar
- [17]Ekkernkamp E, Storre JH, Windisch W, Dreher M (2014) Impact of intelligent volume-assured pressure support on sleep quality in stable hypercapnic chronic obstructive pulmonary disease patients: a randomized, crossover study. Respiration 88(4):270–276CrossRefPubMedGoogle Scholar
- [18]Kelly JL, Jaye J, Pickersgill RE, Chatwin M, Morrell MJ, Simonds AK (2014) Randomized trial of 'intelligent' autotitrating ventilation versus standard pressure support non-invasive ventilation: impact on adherence and physiological outcomes. Respirology 19(4):596–603CrossRefPubMedGoogle Scholar
- [19]Murphy PB, Davidson C, Hind MD, Simonds A, Williams AJ, Hopkinson NS et al (2012) Volume targeted versus pressure support non-invasive ventilation in patients with super obesity and chronic respiratory failure: a randomised controlled trial. Thorax 67(8):727–734CrossRefPubMedGoogle Scholar
- [20]Storre JH, Seuthe B, Fiechter R, Milioglou S, Dreher M, Sorichter S et al (2006) Average volume-assured pressure support in obesity hypoventilation: a randomized crossover trial. Chest 130(3):815–821CrossRefPubMedGoogle Scholar
- [21]Guo YF, Sforza E, Janssens JP (2007) Respiratory patterns during sleep in obesity-hypoventilation patients treated with nocturnal pressure support: a preliminary report. Chest 131(4):1090–1099CrossRefPubMedGoogle Scholar
- [22]Crescimanno G, Canino M, Marrone O (2012) Asynchronies and sleep disruption in neuromuscular patients under home noninvasive ventilation. Respir Med 106(10):1478–1485CrossRefPubMedGoogle Scholar
- [23]Dellweg D, Barchfeld T, Klauke M, Eiger G (2009) Respiratory muscle unloading during auto-adaptive non-invasive ventilation. Respir Med 103(11):1706–1712CrossRefPubMedGoogle Scholar
- [24]Kohler D, Dellweg D, Barchfeld T, Klauke M, Tiemann B (2008) Time-adaptive mode, a new ventilation form for the treatment of respiratory insufficiency–a self-learning system. Pneumologie 62(9):527–532CrossRefPubMedGoogle Scholar
- [25]Windisch W, Walterspacher S, Siemon K, Geiseler J, Sitter H (2010) Guidelines for non-invasive and invasive mechanical ventilation for treatment of chronic respiratory failure. Published by the German Society for Pneumology (DGP). Pneumologie 64(10):640–652CrossRefPubMedGoogle Scholar
Copyright information
© Springer-Verlag GmbH Deutschland, ein Teil von Springer Nature 2018