Archive for the ‘Rickettsia’ Category

Fire – Good News for Tick Reduction

Fire & Ticks: The Impacts of Long-term Prescribed Fire on Tick Populations & Tick-borne Disease Risk

Approx. 1 hour

Published on Mar 29, 2018

This webinar by Dr. Liz Gleim, Assistant Professor of Biology & Environmental Studies from Hollins University explores the impacts of long-term prescribed fire on ticks & tick-borne disease risk and what appears to be some promising results linking fire & reducing disease risk.

Webinar found on the NAFSE website, www.firesciencenorthatlantic.org.

https://madisonarealymesupportgroup.com/wp-content/uploads/2018/04/4101b-gleim_tick26fire_webinar_final.pdf

(slide show in link)

The research conducted in southwest Georgia concerned four tick species (slide 2):

  • Lone Star Tick – known for causing Human Monocytic Ehrlichiosis (HME), Ehrlichiosis ewingii (STARI)
  • Gulf Coast Tick – known for causing Rickettsiosis
  • American Dog Tick – known for causing Rocky Mountain Spotted Fever (RMSF)
  • Black Legged Tick – known for causing Lyme Disease (LD), Human granulocytic anaplasmosis (HGA), and Babesiosis

Prior research (slide 5) have shown a discrepancy regarding whether or not controlled fire reduces tick abundance over time.  Gleim found that these prior studies did not take into account “real-world” management practices such as they were conducted in small areas and consisted of single-burns.

Gleim’s study consisted of 21 Total sites in 4 different categories (slide 7):

  1. 8 burned sites surrounded by burned areas
  2. 5 burned sites surrounded by unburned areas
  3. 5 unburned sites surrounded by unburned areas
  4. 3 control unburned sites surrounded by unburned areas

The study went for 2 years in which they did monthly tick surveys, took weather data, and did vegetative and host surveys (slide 8).  In the two years they collected over 47,000 ticks.

Tick abundance was in the following order (slide 10):

  1. Lone Star Tick
  2. Black Legged Tick
  3. Gulf Coast Tick
  4. American Dog Tick

Regarding fire on tick populations, they found the burned areas “flatlined” the tick populations whereas the control sites had typical tick abundance (slide 11) .  

Greater than 95% leaf litter = 2X more ticks (slide 12)

High tree density = 6X more ticks

Regarding black legged ticks:

Burning reduced the black legged tick population by 78%

High tree density = 17X more ticks

Recent precipitation = 2X more ticks

Gleim was concerned about the effects of red imported fire ants (RIFA) on the ticks (slide 14 & 15)

Ticks:  Evidence has shown that Imported fire ants reduce populations of certain tick species by preying on engorged female ticks filled with blood and eggs or small hatching ticks. Non-engorged ticks freeze in place and “play possum” when examined by a foraging ant, thus escaping their fate as ant food!   http://articles.extension.org/pages/60922/what-do-fire-ants-eat

There is limited data only the effects of RIFA on Lone Star Ticks.

So they did 3 treatments (slide 16) putting engorged Lone Star & Gulf Coast Ticks as well as nymphs into each enclosure and releasing them them during months that they were determined to be naturally active (slide 17):

  1. Burned habitat with Fire Ants
  2. Burned habitat without Fire Ants (this doesn’t happen naturally)
  3. Unburned habitat without Fire Ants (this doesn’t happen naturally)

They found (slide 18) no significant effect of RIFA on either tick species and that Gulf Coast Ticks did better than the Lone Star Ticks in the burned habitat with higher temperatures and the Lone Star Ticks did better in the unburned habitat.  The ticks did not have to survive burning; however, they had to survive the habitat after the vegetation was alive and well.

They found (slide 19) that burning gave an open canopy with sunlight being able to reach through to the forest floor causing higher temps and lower humidity.  The unburned sites conversely had closed canopy with a leaf litter understory causing lower temps and higher humidity which is more conducive for tick populations.

In essence – fire causes a forest structure that is less conducive to tick populations and lowers ticks and pathogen prevalence (slide 20).

The bottom line is they found (slide 21):

No Borrelia burgdorferi in the black legged ticks they collected.

  • .02 infected ticks per hour in all burned sites
  • .70 infected ticks per hour in unburned sites

Burning gave a 98% reduction in ticks.

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**Comment**

Well, now we know. Burning SIGNIFICANTLY REDUCES TICKS.  Let there be no question.

I’m very thankful for this work as it lays to rest the idea that burning isn’t worth it.  I would say that a 78-98% reduction in ticks to be worth it!

http://journals.plos.org/plosone/article?id=10.1371/journal.pone.0112174   These data indicate that regular prescribed burning is an effective tool for reducing tick populations and ultimately may reduce risk of tick-borne disease.

Those of you in states where funding is increasing for tick reduction, copy this off and get it to your representatives.  Burning is not toxic like pesticides often used to reduce ticks.  It also works.  I have to think it’s economical compared to many other options as well.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Category:

Babesia, Lyme, research, Rickettsia, Rocky Mountain Spotted Fever, Testing, Ticks

Ticks & TBI’s in Kentucky

https://www.ncbi.nlm.nih.gov/pubmed/29502988

Ticks Tick Borne Dis. 2018 Mar 1. pii: S1877-959X(17)30571-X. doi: 10.1016/j.ttbdis.2018.02.016. [Epub ahead of print]

Widespread distribution of ticks and selected tick-borne pathogens in Kentucky (USA).

Lockwood BH1, Stasiak I2, Pfaff MA1, Cleveland CA1, Yabsley MJ3.
Author information

Abstract
The geographical distribution of Ixodes scapularis and Amblyomma maculatum ticks is poorly understood in Kentucky. We conducted a convenience survey of wildlife species (white-tailed deer (Odocoileus virginianus), elk (Cervus canadensis) and black bears (Ursus americanus) for ticks from October 2015 to January 2017. We detected four tick species including Amblyomma americanum, Dermacentor albipictus, I. scapularis and A. maculatum. Although the former two tick species were previously known to be widely distributed in Kentucky, we also found that I. scapularis and A. maculatum were also widespread. Because of the limited data available for pathogens from I. scapularis and A. maculatum, we tested them for Borrelia and Rickettsia spp. by polymerase chain reaction assays. Prevalence of Borrelia burgdorferi sensu stricto and Rickettsia parkeri were 11% and 3%, respectively. These data indicate that public health measures are important to prevent tick-borne diseases in Kentucky.

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**Comment**

The data is going to continue to pour in from all over.  Those in the South have long been pushed aside, denied diagnosis and treatment due to certain ticks or diseases. “not being there.”  Somebody has to be the first case, but if you don’t allow a first case, “it doesn’t exist there.”  It’s like being trapped in a Kafka novel with no way out.

https://madisonarealymesupportgroup.com/2017/10/06/remembering-dr-masters-the-rebel-for-lyme-patients-who-took-on-the-cdc-single-handedly/

https://madisonarealymesupportgroup.com/2016/09/24/arkansas-kids-denied-lyme-treatment/

https://madisonarealymesupportgroup.com/2018/02/06/lyme-in-the-southern-hemisphere-sexual-transmission/

https://madisonarealymesupportgroup.com/2018/03/11/range-expansion-of-tick-disease-vectors-in-north-america-implications-for-spread-of-tick-borne-disease/

I wish they would test these ticks for more than the one or two pathogens that seem popular these days.  There are approximately 16 diseases that ticks can spread.  Authorities are still bickering about Bartonella being transmitted by ticks; however, the majority of patients I work with all have Bart, making transmission by ticks highly probable. 

https://madisonarealymesupportgroup.com/2017/07/01/one-tick-bite-could-put-you-at-risk-for-at-least-6-different-diseases/ (The number is more like 16 not 6.  It’s probably more than that.)

Babesiosis
Bartonellosis
Borrelia miyamotoi
Bourbon Virus
Colorado Tick Fever
Ehrlichiosis/Anaplasmosis
Heartland Virus
Meat Allergy/Alpha Gal
Pacific Coast Tick Fever: Richettsia philipii
Powassan Encephalitis
Q Fever
Rickettsia parkeri Richettsiosis
Rocky Mountain Spotted Fever
STARI: Southern Tick-Associated Rash Illness
Rick Paralysis
Tularemia

Then there’s the whole issue of other insects being able to transmit.

We have a lot of work to do and a lot of answers to find.

 

 

Category:

Lyme, research, Rickettsia, Testing, Ticks, Transmission

PCR of Skin Infections With Eschar on Travelers – Rickettsia Most Detected

https://www.ncbi.nlm.nih.gov/m/pubmed/29501703/

Seek and Find! PCR analyses of skin infections in West-European travelers returning from abroad with an eschar.

 Travel Med Infect Dis. 2018.

Abstract

BACKGROUND: Skin infections are among the leading causes of diseases in travelers. Diagnosing pathogens could be difficult.

METHOD: We applied molecular assays for the diagnostic of a large collection of skin biopsies and swabs from travelers with suspected skin infections. All samples were tested by qPCR for Coxiella burnetti, Bartonella sp., Rickettsia sp., Borrelia sp., Ehrlichia sp., Tropheryma whipplei, Francisella tularensis, Mycobacteria sp., Staphylococcus aureus, Streptococcus pyogenes, Leishmania spp., Ortho poxvirus and Para poxvirus and then screened for the presence of bacteria by PCR amplification and sequencing, targeting the 16S rRNA gene.

RESULTS: From January 2009 to January 2017, 100 international travelers presenting with a suspected skin infection were enrolled. We detected 51 patients with an identified pathogen on skin samples. Travelers presenting with eschars were more likely to have a positive PCR sample (n = 44/76, 57.9%) compared to other patients (n = 7/24, 29.2%). Spotted fever group Rickettsia (n = 28) was the most frequently detected pathogens (19 R. africae, 6 R. conorii, 3 R. mongolitimonae); S. aureus were detected in 11 patients; S. pyogenes in 3; Leishmania sp.; M. leprae and B. henselae in 1 patient, respectively.

CONCLUSION: By targeting the most commonly encountered causative agents of travel-related skin infections, our strategy provides a sensitive and rapid diagnostic method.

 

 

Category:

Bartonella, Ehrlichiosis, Lyme, Mycoplasma, research, Rickettsia, Tularemia, Viruses

Italy – 5 year Tick Survey

https://www.ncbi.nlm.nih.gov/m/pubmed/29477960/

A five-year survey of tick species and identification of tick-borne bacteria in Sardinia, Italy.

Authors

Chisu V1Foxi C2Mannu R3Satta G2Masala G2.

 Ticks Tick Borne Dis. 2018.

Abstract

Sardinia is a hotspot for studying tick-borne diseases in the Mediterranean region, where cases of notifiable tick-borne diseases are increasing. The aim of this study was to determine the presence of tick-borne bacteria of medical and veterinary importance in ixodid ticks collected from domestic and wild animals, humans, and vegetation from different collection sites in Sardinia. Using standard PCR and sequencing techniques, the presence of Rickettsia, Anaplasma, Ehrlichia, and Bartonella species, as well as Coxiella burnetii was evaluated. A total of 1619 ticks were morphologically identified as Rhipicephalus sanguineus sensu lato, R. bursa, R. annulatus, Dermacentor marginatus, Haemaphysalis punctata, Ha. sulcata, Hyalomma lusitanicum, H. marginatum, Ixodes festai (sometimes referred to erroneously as I. ventalloi), and Argas reflexus. Results indicated the presence of several circulating pathogens in Sardinian ticks. DNA of Rickettsia species was detected in 58 out of 1619 (4%) belonging to R. sanguineus s.l., D. marginatus, Ha. punctata, H. marginatum, and I. festai species. Ehrlichia canis DNA was detected in 33 out of 1619 ticks (2%) belonging to R. sanguineus s.l., R. bursa, and Ha. punctata species. A total of 61 out of 1619 (4%) ticks (R. sanguineus s. l., R. bursa, Ha. punctata, and I. festai) tested positive for Anaplasma spp. Coxiella burnetii was detected in 21 out of 1619 (1%) ticks belonging to R. sanguineus s.l., R. bursa, R. annulatus, and H. marginatum species. Five R. sanguineus s.l. and one R. bursa ticks were positive for the presence of Bartonella sp. 16S rRNA gene. Our findings expand the knowledge on tick-borne microorganism repertoires and tick distribution in Sardinia. Tick distribution should be monitored for effective control of these arthropods and the infections they transmit.

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For More:  https://madisonarealymesupportgroup.com/2017/07/01/one-tick-bite-could-put-you-at-risk-for-at-least-6-different-diseases/

https://madisonarealymesupportgroup.com/2017/10/28/lyme-wars-part-5-coinfections/

https://madisonarealymesupportgroup.com/2017/05/01/co-infection-of-ticks-the-rule-rather-than-the-exception/

https://madisonarealymesupportgroup.com/2018/02/16/tbd-serochip-will-identify-six-tick-borne-pathogens/

Category:

Anaplasmosis, Bartonella, Rickettsia, Ticks

Neglected Vector-borne Zoonoses in Europe

https://www.ncbi.nlm.nih.gov/m/pubmed/29426471/

Neglected vector-borne zoonoses in Europe: Into the wild.

Tomassone L1Berriatua E2De Sousa R3Duscher GG4Mihalca AD5Silaghi C6Sprong H7Zintl A8. Vet Parasitol. 2018.

Abstract

Wild vertebrates are involved in the transmission cycles of numerous pathogens. Additionally, they can affect the abundance of arthropod vectors. Urbanization, landscape and climate changes, and the adaptation of vectors and wildlife to human habitats represent complex and evolving scenarios, which affect the interface of vector, wildlife and human populations, frequently with a consequent increase in zoonotic risk. While considerable attention has focused on these interrelations with regard to certain major vector-borne pathogens such as Borrelia burgdorferi s.l. and tick-borne encephalitis virus, information regarding many other zoonotic pathogens is more dispersed. In this review, we discuss the possible role of wildlife in the maintenance and spread of some of these neglected zoonoses in Europe. We present case studies on the role of rodents in the cycles of Bartonella spp., of wild ungulates in the cycle of Babesia spp., and of various wildlife species in the life cycle of Leishmania infantum, Anaplasma phagocytophilum and Rickettsia spp.

These examples highlight the usefulness of surveillance strategies focused on neglected zoonotic agents in wildlife as a source of valuable information for health professionals, nature managers and (local) decision-makers. These benefits could be further enhanced by increased collaboration between researchers and stakeholders across Europe and a more harmonised and coordinated approach for data collection.

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**Comment**

They are neglected in the U.S. too, but all play a significant role in patient case complexity.

Category:

Anaplasmosis, Babesia, Bartonella, research, Rickettsia