Targeted immunization strategies

Part of a series on
Network science
Internet_map_1024.jpg
Network types
Graphs
Features
Types
Models
Topology
Dynamics
  • Lists
  • Categories

Targeted immunization strategies are approaches designed to increase the immunization level of populations and decrease the chances of epidemic outbreaks.[1] Though often in regards to use in healthcare practices and the administration of vaccines to prevent biological epidemic outbreaks,[2] these strategies refer in general to immunization schemes in complex networks, biological, social or artificial in nature.[1] Identification of at-risk groups and individuals with higher odds of spreading the disease often plays an important role in these strategies, since targeted immunization in high-risk groups is necessary for effective eradication efforts and has a higher return on investment than immunizing larger but lower-risk groups.[1][3][4]

Background

The success of vaccines in preventing major outbreaks relies on the mechanism of herd immunity, also known as community immunity, where the immunization of individuals provides protection for not only the individuals, but also the community at large.[5] In cases of biological contagions such as influenza, measles, and chicken pox, immunizing a critical community size can provide protection against the disease for members who cannot be vaccinated themselves (infants, pregnant women, and immunocompromised individuals). Often however these vaccine programmes require the immunization of a large majority of the population to provide herd immunity.[6] A few successful vaccine programmes have led to the eradication of infectious diseases like small pox[7] and rinderpest, and the near eradication of polio,[8] which plagued the world before the second half of the 20th century.[9][10]

Network-based strategies

More recently researchers have looked at exploiting network connectivity properties to better understand and design immunization strategies to prevent major epidemic outbreaks.[11] Many real networks like the Internet, World Wide Web, and even sexual contact networks[12] have been shown to be scale-free networks and as such exhibit a power-law distribution for the degree distribution. In large networks this results in the vast majority of nodes (individuals in social networks) having few connections or low degree k, while a few "hubs" have many more connections than the average <k>.[13] This wide variability (heterogeneity) in degree offers immunization strategies based on targeting members of the network according to their connectivity rather than random immunization of the network. In epidemic modeling on scale-free networks, targeted immunization schemes can considerably lower the vulnerability of a network to epidemic outbreaks over random immunization schemes. Typically these strategies result in the need for far fewer nodes to be immunized in order to provide the same level of protection to the entire network as in random immunization.[1][14] In circumstances where vaccines are scarce, efficient immunization strategies become necessary to preventing infectious outbreaks.[15]

Examples

A common approach for targeted immunization studies in scale-free networks focuses on targeting the highest degree nodes for immunization. These nodes are the most highly connected in the network, making them more likely to spread the contagion if infected. Immunizing this segment of the network can drastically reduce the impact of the disease on the network and requires the immunization of far fewer nodes compared to randomly selecting nodes.[1] However, this strategy relies on knowing the global structure of the network, which may not always be practical.[citation needed]

A recent centrality measure, Percolation Centrality, introduced by Piraveenan et al.[16] is particularly useful in identifying nodes for vaccination based on the network topology. Unlike node degree which depends on topology alone, however, percolation centrality takes into account the topological importance of a node as well as its distance from infected nodes in deciding its overall importance. Piraveenan et al.[16] has shown that percolation centrality-based vaccination is particularly effective when the proportion of people already infected is on the same order of magnitude as the number of people who could be vaccinated before the disease spreads much further. If infection spread is at its infancy, then ring-vaccination surrounding the source of infection is most effective, whereas if the proportion of people already infected is much higher than the number of people that could be vaccinated quickly, then vaccination will only help those who are vaccinated and herd immunity cannot be achieved.[6] Percolation centrality-based vaccination is most effective in the critical scenario where the infection has already spread too far to be completely surrounded by ring-vaccination, yet not spread wide enough so that it cannot be contained by strategic vaccination. Nevertheless, Percolation Centrality also needs full network topology to be computed, and thus is more useful in higher levels of abstraction (for example, networks of townships rather than social networks of individuals), where the corresponding network topology can more readily be obtained.[citation needed]

Increasing immunization coverage

Millions of children worldwide do not receive all of the routine vaccinations as per their national schedule. As immunization is a powerful public health strategy for improving child survival, it is important to determine what strategies work best to increase coverage. A Cochrane review assessed the effectiveness of intervention strategies to boost and sustain high childhood immunization coverage in low- and middle-income countries.[17] Forty-one trials were included but most of the evidence was of low quality.[17] Providing parents and other community members with information on immunization, health education at facilities in combination with redesigned immunization reminder cards, regular immunization outreach with and without household incentives, home visits, and integration of immunization with other services may improve childhood immunization coverage in low-and middle-income countries.[17]

See also

References

  1. ^ a b c d e Pastor-Satorras R, Vespignani A (March 2002). "Immunization of complex networks". Physical Review E. 65 (3 Pt 2A): 036104. arXiv:cond-mat/0107066. Bibcode:2002PhRvE..65c6104P. doi:10.1103/PhysRevE.65.036104. PMID 11909162. S2CID 15581869.
  2. ^ "Vaccines and immunization". www.cdc.gov/vaccines/. Center for Disease Control and Prevention. Retrieved 17 November 2014.
  3. ^ Piddle S (October 14, 2014). "VNA nurses bring shots to school". Clinton Herald. Retrieved 15 November 2014.
  4. ^ von Csefalvay C (2023). "Modeling the control of infectious disease". Computational Modeling of Infectious Disease. Elsevier. pp. 173–215. doi:10.1016/b978-0-32-395389-4.00015-3. ISBN 978-0-323-95389-4.
  5. ^ John TJ, Samuel R (2000-07-01). "Herd immunity and herd effect: new insights and definitions". European Journal of Epidemiology. 16 (7): 601–606. doi:10.1023/A:1007626510002. PMID 11078115. S2CID 23504580.
  6. ^ a b "Community Immunity ("Herd" Immunity)". National Institute of Allergy and Infectious Diseases. Retrieved 7 April 2014.
  7. ^ Bazin H (2000). The Eradication of Small Pox. London: Academic Press. ISBN 978-0-12-083475-4.
  8. ^ "Updates on CDC's Polio Eradication Efforts". www.cdc.gov/polio. Center for Disease Control and Prevention. Retrieved 17 November 2014.
  9. ^ Lewis T (October 28, 2014). "Polio Vaccine: How the US' Most Feared Disease Was Eradicated". LiveScience. Purch. Retrieved 15 November 2014.
  10. ^ McNeil Jr DG (May 5, 2014). "Polio's Return After Near Eradication Prompts a Global Health Warning". The New York Times. Retrieved 18 November 2014.
  11. ^ Campbell E, Salathé M (May 28, 2013). "Complex social contagion makes networks more vulnerable to disease outbreaks". Scientific Reports. 3: 1905. arXiv:1211.0518. Bibcode:2013NatSR...3E1905C. doi:10.1038/srep01905. PMC 3664906. PMID 23712758.
  12. ^ Liljeros F, Edling CR, Amaral LA, Stanley HE, Aberg Y (June 2001). "The web of human sexual contacts". Nature. 411 (6840): 907–908. arXiv:cond-mat/0106507. Bibcode:2001Natur.411..907L. doi:10.1038/35082140. PMID 11418846. S2CID 14559344.
  13. ^ Barabasi AL, Albert R (October 1999). "Emergence of scaling in random networks". Science. 286 (5439): 509–512. arXiv:cond-mat/9910332. Bibcode:1999Sci...286..509B. doi:10.1126/science.286.5439.509. PMID 10521342. S2CID 524106.
  14. ^ Tanaka G, Urabe C, Aihara K (July 2014). "Random and targeted interventions for epidemic control in metapopulation models". Scientific Reports. 4 (5522): 5522. Bibcode:2014NatSR...4E5522T. doi:10.1038/srep05522. PMC 4099978. PMID 25026972.
  15. ^ Glasser J, Taneri D, Feng Z, Chuang JH, Tüll P, Thompson W, et al. (September 2010). "Evaluation of targeted influenza vaccination strategies via population modeling". PLOS ONE. 5 (9): e12777. Bibcode:2010PLoSO...512777G. doi:10.1371/journal.pone.0012777. PMC 2941445. PMID 20862297.
  16. ^ a b Piraveenan M, Prokopenko M, Hossain L (2013-01-22). "Percolation centrality: quantifying graph-theoretic impact of nodes during percolation in networks". PLOS ONE. 8 (1): e53095. Bibcode:2013PLoSO...853095P. doi:10.1371/journal.pone.0053095. PMC 3551907. PMID 23349699.
  17. ^ a b c Oyo-Ita A, Oduwole O, Arikpo D, Effa EE, Esu EB, Balakrishna Y, et al. (December 2023). "Interventions for improving coverage of childhood immunisation in low- and middle-income countries". The Cochrane Database of Systematic Reviews. 2023 (12): CD008145. doi:10.1002/14651858.CD008145.pub4. PMC 10698843. PMID 38054505.

Read other articles:

Pembicaraan Pengguna:Blue Sonic

Halaman ini diarsipkan secara otomatis oleh HsfBot (lihat instruksi) Pengguna ini sedang sibuk di dunia nyata dan mungkin tidak menanggapi pesan dengan cepat. Halo, Selamat datang di Wikipedia bahasa Indonesia! Memulai Bacalah halaman Pengantar Wikipedia terlebih dahulu. Baca juga informasi tentang berkontribusi di Wikipedia. Tuliskan juga sedikit profil Anda di Pengguna:, halaman pribadi Anda, agar kami dapat lebih mengenal Anda. Lihat pula aturan yang disederhanakan sebelum melanjutkan. Ti...

 

 

Mitch Ryder

Pour les articles homonymes, voir Ryder. Mitch RyderMitch Ryder, 2023BiographieNaissance 26 février 1945 (79 ans)LivoniaNationalité américaineFormation Warren High School (en)Activités Musicien, chanteur, auteur-compositeurPériode d'activité depuis 1962Autres informationsLabels Dot Records (en), Line Records (d)Genre artistique Rock 'n' rollSite web www.mitchryder.netmodifier - modifier le code - modifier Wikidata Mitch Ryder (de son vrai nom William Levise Jr.) est un chanteur de...

 

 

Chantepérier

Chantepérier Village du Périer. Administration Pays France Région Auvergne-Rhône-Alpes Département Isère Arrondissement Grenoble Intercommunalité Communauté de communes de la Matheysine Maire Mandat Christelle Meheut 2020-2026 Code postal 38740 Code commune 38073 Démographie Populationmunicipale 206 hab. (2021) Densité 2,5 hab./km2 Géographie Coordonnées 44° 59′ 05″ nord, 5° 58′ 09″ est Altitude Min. 897 mMax. 3 023 ...

Animal Crossing: Wild World

Animal Crossing: Wild World PublikasiJP: 23 November 2005NA: 5 Desembe 2005AU: 8 Desember 2005EU: 31 Maret 2006GenreSimulasi kehidupanLatar tempatAnimal Crossing universe (en) Bahasa Daftar banyak bahasa 60 Karakteristik teknisPlatformNintendo DS Modepermainan video multipemain dan Permainan video pemain tunggal Formatunduhan digital dan Nintendo DS Game Card (en) Jumlah minimum pemain1 Jumlah maksimal pemain4 Format kode Daftar 30 Informasi pengembangPengembangNintendo EADPenyuntingNintendo ...

 

 

Stasiun Serpong

Stasiun Serpong R08 Stasiun SerpongLokasiJalan Stasiun SerpongSerpong, Serpong, Tangerang Selatan, Banten 15311IndonesiaKoordinat6°19′12.52″S 106°39′54.54″E / 6.3201444°S 106.6651500°E / -6.3201444; 106.6651500Koordinat: 6°19′12.52″S 106°39′54.54″E / 6.3201444°S 106.6651500°E / -6.3201444; 106.6651500Ketinggian+46 mOperator KAI Commuter Letakkm 31+203 lintas Angke–Tanah Abang–Rangkasbitung–Merak[1] Jumlah pe...

 

 

Newsboy Legion

Fictional kid gang in the DC Comics Universe Newsboy LegionThe original Newsboy Legion (from left to right: Gabby, Bigwords, Tommy, and Scrapper) in Star Spangled #7 (April 1942).Art by Jack Kirby.Publication informationPublisherDC ComicsFirst appearanceStar-Spangled Comics #7 (April 1942)Created byJoe SimonJack KirbyIn-story informationMember(s)Tommy TompkinsBig WordsGabbyScrapperFlippa Dippa The Newsboy Legion is a teenage vigilante group in the DC Comics Universe. Created by Joe Simon and ...

Koch snowflake

Fractal curve The first four iterations of the Koch snowflake The first seven iterations in animation Zooming into a vertex of the Koch curve Zooming into a point that is not a vertex may cause the curve to rotate Koch antisnowflakeFirst four iterationsSixth iteration The Koch snowflake (also known as the Koch curve, Koch star, or Koch island[1][2]) is a fractal curve and one of the earliest fractals to have been described. It is based on the Koch curve, which appeared in a 19...

 

 

Cotton Bowl (stadion)

Untuk stadion sepak bola Amerika di Dallas, Texas, Amerika Serikat, lihat Cotton Bowl (disambiguasi). Stadion Cotton BowlThe House That Doak BuiltWest grandstand main entrance in 2016Nama lamaStadion Fair Park(1930–1936)Alamat1300 Robert Cullum Blvd.LokasiDallas, Texas, Amerika SerikatPemilikPemerintah Kota DallasKapasitas92,100[1]Rekor kehadiran96,009[2]PermukaanRumput alami(1930–1969, dari 1994)AstroTurf (1970–1993)KonstruksiMulai pembangunan1930[3]Dib...

 

 

Athletics at the 1958 British Empire and Commonwealth Games – Women's shot put

Athletics at the 1958 BritishEmpire andCommonwealth GamesTrack events100 ydmenwomen220 ydmenwomen440 ydmen880 ydmen1 milemen3 milesmen6 milesmen80 m hurdleswomen120 yd hurdlesmen440 yd hurdlesmen4 × 110 yd relaymenwomen4 × 440 yd relaymenRoad eventsMarathonmenField eventsHigh jumpmenwomenPole vaultmenLong jumpmenwomenTriple jumpmenShot putmenwomenDiscus throwmenwomenHammer throwmenJavelin throwmenwomenvte The women's shot put event at the 1958 British Empire and Commonwealth Games was held...

世界政區索引

此條目可能包含不适用或被曲解的引用资料,部分内容的准确性无法被证實。 (2023年1月5日)请协助校核其中的错误以改善这篇条目。详情请参见条目的讨论页。 各国相关 主題列表 索引 国内生产总值 石油储量 国防预算 武装部队(军事) 官方语言 人口統計 人口密度 生育率 出生率 死亡率 自杀率 谋杀率 失业率 储蓄率 识字率 出口额 进口额 煤产量 发电量 监禁率 死刑 国债 ...

 

 

ヨハネス12世 (ローマ教皇)

ヨハネス12世 第130代 ローマ教皇 教皇就任 955年12月16日教皇離任 964年5月14日先代 アガペトゥス2世次代 レオ8世個人情報出生 937年スポレート公国(中部イタリア)スポレート死去 964年5月14日 教皇領、ローマ原国籍 スポレート公国親 父アルベリーコ2世(スポレート公)、母アルダその他のヨハネステンプレートを表示 ヨハネス12世(Ioannes XII、937年 - 964年5月14日)は、ロ...

 

 

عملية الموجة العارمة

44°56′N 26°1′E / 44.933°N 26.017°E / 44.933; 26.017 عملية الموجة العارمة جزء من حملة النفط خلال الحرب العالمية الثانية طائرة من طراز بي-24 ليبيراتور المعروفة باسم المنوم أثناء قصف معمل تكرير بلويشت أسترا رومانيا خلال عملية الموجة العارمة[1][2] معلومات عامة التاريخ 1 أغسطس ...

Dartford railway station

Railway station in Kent, England Dartford DartfordLocation of Dartford in KentLocationDartfordLocal authorityBorough of DartfordGrid referenceTQ543743Managed bySoutheasternStation codeDFDDfT categoryC1Number of platforms4AccessibleYesFare zone8National Rail annual entry and exit2018–19 4.623 million[1]– interchange  0.402 million[1]2019–20 4.659 million[1]– interchange  0.333 million[1]2020–21 1.485 million[1]– interchange  0....

 

 

Союз визволення України

Союз визволення УкраїниКраїна  Австро-УгорщинаГолова партії Олександр Скоропис-Йолтуховський Маркіян Меленський Володимир Дорошенко Дмитро ДонцовДата заснування 4 серпня 1914Дата розпуску 1 травня 1918 Сою́з ви́зволення Украї́ни (СВУ) — політична організація, ...

 

 

Fislis

Fisliscomune Fislis – Veduta LocalizzazioneStato Francia RegioneGrand Est Dipartimento Alto Reno ArrondissementAltkirch CantoneAltkirch TerritorioCoordinate47°30′N 7°22′E47°30′N, 7°22′E (Fislis) Superficie7,6 km² Abitanti443[1] (2009) Densità58,29 ab./km² Altre informazioniCod. postale68480 Fuso orarioUTC+1 Codice INSEE68092 CartografiaFislis Sito istituzionaleModifica dati su Wikidata · Manuale Fislis è un comune francese di 443 abitanti situat...

Retrofitting

Retrofit redirects here. For other uses, see Retrofit (disambiguation). Addition of new technology or features to older systems In this example of retrofitting (interior view on left, exterior on right), a set of modern door-opening buttons has been retrofitted to this British Rail Class 483 electric multiple unit, which was derived from 1938 tube stock. Retrofitting is the addition of new technology or features to older systems. Retrofits can happen for a number of reasons, for example with ...

 

 

Velie

Dieser Artikel beschreibt den US-amerikanischen Personenkraftwagen. Für den Nunatak im Ellsworthland siehe Velie-Nunatak. Velie Biltwel Six-28 („Light Six“) (1917) in einer zeitgenössischen Werbeschrift Velie Modell 34 Touring (1920) Velie Monocoupe 90 Velie war eine US-amerikanische Automarke aus der Zeit von 1909 bis 1928. Hersteller war bis 1916 die Velie Motor Vehicle Company und danach die Velie Motors Corporation (auch Velie Motor Corporation geschrieben) aus Moline in Illinois. ...

 

 

吉岡茉祐

「吉岡麻耶」とは別人です。 この記事の出典や参考文献は、一次資料や記事主題の関係者による情報源に頼っています。 信頼できる第三者情報源とされる出典の追加が求められています。出典検索?: 吉岡茉祐 – ニュース · 書籍 · スカラー · CiNii · J-STAGE · NDL · dlib.jp · ジャパンサーチ · TWL(2020年1月) よしおか まゆ吉岡 茉...

سياسة نفطية

نظرية قمة هوبرت للبترول التي وضعها عام 1956 ويؤيدها الإنتاج الأمريكي ولإنتاج النرويجي للنفط. تلعب سياسة النفط دورا رئيسيا في الاقتصاد العالمي. فعلي النفط يقع عاتق إنتاج الطاقة سواء الطاقة الكهربائية أو مستخلصات النفط كالبنزين والديزل التي تسيّر المواصلات والسيارات وتمد ال...

 

 

Carlo Collodi

Disambiguazione – Collodi rimanda qui. Se stai cercando altri significati, vedi Collodi (disambigua). Carlo Collodi Carlo Collodi, pseudonimo di Carlo Lorenzini (Firenze, 24 novembre 1826 – Firenze, 26 ottobre 1890), è stato uno scrittore e giornalista italiano. È divenuto celebre per essere stato l'autore del romanzo Le avventure di Pinocchio. Storia di un burattino, spesso noto semplicemente come Pinocchio, diventato uno dei grandi classici della letteratura di tutto il mondo...