From basic science knowledge to clinical understanding

Wilhelmsson, Niklas,

January 2010

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2010.

THE EFFECT OF PPARγ ACTIVATION BY PIOGLITAZONE ON THE LIPOPOLYSACCHARIDE-INDUCED PGE₂ AND NO PRODUCTION: POTENTIALUNDERLYING ALTERATION OF SIGNALING TRANSDUCTION

Xing, Bin

01 January 2008

Microglia-mediated neuroinflammation plays an important role in the pathogenesis of Parkinson's disease (PD). Uncontrolled microglia activation produces major proinflammatory factors including cyclooxygenase 2 (COX-2) and inducible nitric oxide synthase (iNOS) that may cause dopaminergic neurodegeneration. Peroxisome proliferator-activated receptor γ (PPARγ) agonist pioglitazone has potent antiinflammatory property. We hypothesize pioglitazone protects dopaminergic neuron from lipopolysaccharide (LPS)-induced neurotoxicity by interacting with relevant signal pathways, inhibiting microglial activation and decreasing inflammatory mediators. First, the neuroprotection of pioglitazone was explored. Second, the signaling transductions such as jun N-terminal kinase (JNK) and the interference with these pathways by pioglitazone were investigated. Third, the effect of pioglitazone on these pathways-mediated PGE2 / nitric oxide (NO) generation was investigated. Finally, the effect of PPARγ antagonist on the inhibition of PGE2 / NO by pioglitazone was explored. The results show that LPS neurotoxicity is microglia-dependent, and pioglitazone protects neurons against LPS insult possibly by suppressing LPS-induced microglia activation and proliferation. Second, pioglitazone protects neurons from COX-2 / PGE2 mediated neuronal loss by interfering with the NF-κB and JNK, in PPARγ-independent mechanisms. Third, pioglitazone significantly inhibits LPS-induced iNOS / NO production, and inhibition of LPS-induced iNOS protects neuron. Fourth, inhibition p38 MAPK reduces LPS-induced NO generation but no effect is found upon JNK inhibition, and pioglitazone inhibits p38 MAPK phosphorylation induced by LPS. In addition, pioglitazone increases PPARγ phosphorylation, followed by the increased PI3K/Akt phosphorylation. Nevertheless, inhibition of PI3K increases LPS-induced p38 MAPK phosphorylation. Inhibition of PI3K eliminates the inhibitive effect of pioglitazone on the LPS-induced NO production, suggesting that the inhibitive effect of pioglitazone on the LPS-induced iNOS and NO might be PI3K-dependent.

Microglia

Dopaminergic neurons

Cytokines

Signaling pathways

Pioglitazone

Medical Anatomy

Medical Neurobiology

THE UNDERLYING MECHANISM(S) OF FASTING INDUCED NEUROPROTECTION AFTER MODERATE TRAUMATIC BRAIN INJURY

Davis, Laurie Michelle Helene

01 January 2008

Traumatic brain injury (TBI) is becoming a national epidemic, as it accounts for 1.5 million cases each year. This disorder affects primarily the young population and elderly. Currently, there is no treatment for TBI, which means that ~2% of the U.S. population is currently living with prolonged neurological damage and dysfunction. Recently, there have been many studies showing that TBI negatively impacts mitochondrial function. It has been proposed that in order to save the cell from destruction mitochondrial function must be preserved. The ketogenic diet, originally designed to mimic fasting physiology, is effective in treating epilepsy. Therefore, we have used fasting as a post injury treatment and attempted to elucidate its underlying mechanism. 24 hours of fasting after a moderate TBI increased tissue sparing, cognitive recovery, improved mitochondrial function, and decreased mitochondrial biomarkers of injury. Fasting results in hypoglycemia, the production of ketones, and the upregulation of free fatty acids (FFA). As such, we investigated the neuroprotective effect of hypoglycemia in the absence of fasting through insulin administration. Insulin administration was not neuroprotective and increased mortality in some treatment groups. However, ketone administration resulted in increased tissue sparing. Also, reduced reactive oxygen species (ROS) production, increased the efficiency of NADH utilization, and increased respiratory function. FFAs and uncoupling proteins (UCP) have been implicated in an endogenously regulated anti-ROS mechanism. FFAs of various chain lengths and saturation were screened for their ability to activate UCP mediated mitochondrial respiration and attenuate ROS production. We also measured FFA levels in serum, brain, and CSF after a 24 hour fast. We also used UCP2 transgenic overexpressing and knockout mice in our CCI injury model, which showed UCP2 overexpression increased tissue sparing, however UCP2 deficient mice did not show a decrease in tissue sparing, compared with their wild type littermates. Together our results indicate that post injury initiated fasting is neuroprotective and that this treatment is able to preserve mitochondrial function. Our work also indicates ketones and UCPs may be working together to preserve mitochondrial and cellular function in a concerted mechanism, and that this cooperative system is the underlying mechanism of fasting induced neuroprotection.

Traumatic Brain Injury

Mitochondria

Ketone

Uncoupling Protein

HIF-1

Medical Anatomy

Medical Neurobiology

DISRUPTIONS IN THE REGULATION OF EXTRACELLULAR GLUTAMATE IN THE RAT CENTRAL NERVOUS SYSTEM AFTER DIFFUSE BRAIN INJURY

Hinzman, Jason Michael

01 January 2012

Glutamate, the predominant excitatory neurotransmitter in the central nervous system, is involved in almost all aspects of neurological function including cognition, motor function, memory, learning, decision making, and neuronal plasticity. For normal neurological function, glutamate signaling must be properly regulated. Disrupted glutamate regulation plays a pivotal role in the acute pathophysiology of traumatic brain injury (TBI), disrupting neuronal signaling, initiating secondary injury cascades, and producing excitotoxicity. Increases in extracellular glutamate have been correlated with unfavorable outcomes in TBI survivors, emphasizing the importance of glutamate regulation. The aim of this thesis was to examine disruptions in the regulation of extracellular glutamate after experimental TBI. In these studies, we used glutamate-sensitive microelectrode arrays (MEAs) to examine the regulation of extracellular glutamate two days after diffuse brain injury. First, we examined which brain regions were vulnerable to post-traumatic increases in extracellular glutamate. We detected significant increases in extracellular glutamate in the dentate gyrus and striatum, which correlated to the severity of brain injury. Second, we examined the regulation of extracellular glutamate by neurons and glia to determine the mechanisms responsible for post-traumatic increases in extracellular glutamate. In the striatum of brain-injured rats, we detected significant disruptions in release of glutamate by neurons and significant decreases in the removal of glutamate from the extracellular space by glia. Third, we examined if a novel therapeutic strategy, a viral-vector mediated gene delivery approach, could improve the regulation of extracellular glutamate. Infusion of an adeno-associated virus expressing a glutamate transporter into the rat striatum produced significant improvements in glutamate clearance, identifying a novel strategy to reduce excitotoxicity. Lastly, we examined the translational potential of MEAs as novel neuromonitoring device for clinical TBI research. Overall, these studies have demonstrated the translational potential of MEAs to aid in the diagnosis and treatment of TBI survivors.

midline fluid percussion injury

amperometry

excitatory amino acid transporters

Medical Anatomy

Medical Neurobiology

CHARACTERIZATION AND OPTIMIZATION OF MICROELECTRODE ARRAYS FOR GLUTAMATE MEASUREMENTS IN THE RAT HIPPOCAMPUS

Talauliker, Pooja Mahendra

01 January 2010

An overarching goal of the Gerhardt laboratory is the development of an implantable neural device that allows for long-term glutamate recordings in the hippocampus. Proper L-glutamate regulation is essential for hippocampal function, while glutamate dysregulation is implicated in many neurodegenerative diseases. Direct evidence for subregional glutamate regulation is lacking in previous in vivo studies because of limitations in the spatio-temporal resolution of conventional experimental techniques. We used novel enzyme-coated microelectrode arrays (MEAs) for rapid measurements (2Hz) of extracellular glutamate in urethane-anesthetized rats. Potassium-evoked glutamate release was highest in the cornu ammonis 1 (CA1) subregion and lowest in the cornu ammonis 3 (CA3). In the dentate gyrus (DG), evoked-glutamate release was diminished at a higher potassium concentration but demonstrated faster release kinetics. These studies are the first to show subregion specific regulation of glutamate release in the hippocampus. To allow for in vivo glutamate measurements in awake rats, we have adapted our MEAs for chronic use. Resting glutamate measurements were obtained up to six days post-implantation but recordings were unreliable at later time points. To determine the cause(s) for recording failure, a detailed investigation of MEA surface characteristics was conducted. Scanning electron microscopy and atomic force microscopy showed that PT sites have unique surface chemistry, a microwell geometry and nanometer-sized features, all of which appear to be favorable for high sensitivity recordings. Accordingly, studies were initiated to improve enzyme coatings using a computer-controlled microprinting system (Microfab Technologies, Plano, TX). Preliminary testing showed that microprinting allowed greater control over the coating process and produced MEAs that met our performance criteria. Our final studies investigated the effects of chronic MEA implantation. Immunohistochemical analysis showed that the MEA produced minimal damage in the hippocampus at all time points from 1 day to 6 months. Additionally, tissue attachment to the MEA surface was minimal. Taken together with previous electrophysiology data supporting that MEAs are functional up to six months, these studies established that our chronic MEAs technology is capable of maintaining a brain-device interface that is both functional and biocompatible for extended periods of time.

Medical Anatomy

Medical Neurobiology

AGE MAY BE HAZARDOUS TO OUTCOME FOLLOWING TRAUMATIC BRAIN INJURY: THE MITOCHONDRIAL CONNECTION

Gilmer, Lesley Knight

01 January 2009

Older individuals sustaining traumatic brain injury (TBI) experience a much higher incidence of morbidity and mortality. This age-related exacerbated response to neurological insult has been demonstrated experimentally in aged animals, which can serve as a model to combat this devastating clinical problem. The reasons for this worse initial response are unknown but may be related to age-related changes in mitochondrial respiration. Evidence is shown that mitochondrial dysfunction occurs early following traumatic brain injury (TBI), persists long after the initial insult, and is severitydependent. Synaptic and extrasynaptic mitochondrial fractions display distinct respiration capacities, stressing the importance to analyze these fractions separately. Sprague- Dawley and Fischer 344 rats, two commonly used strains used in TBI and aging research, were found to show very similar respiration profiles, indicating respiration data are not strain dependent. Neither synaptic nor extrasynaptic mitochondrial respiration significantly declined with age in naïve animals. Only the synaptic fraction displayed significant age-related increases in oxidative damage, measured by 3-nitrotyrosine (3- NT), 4-hydroxynonenal (4-HNE), and protein carbonyls (PC). Alterations in respiration with age appear to be more subtle than previously thought. Subtle declines in respiration and elevated levels of oxidative damage may not to be sufficient to produce detectable deficits until the system is challenged. Following TBI, synaptic mitochondria exhibit dysfunction that increased significantly with age at injury, evident in lower respiratory control ratio (RCR) values and declines in ATP production rates. Furthermore, synaptic mitochondria displayed increased levels of oxidative damage with age and injury, while extrasynaptic mitochondria only displayed significant elevations following the insult. Age-related synaptic mitochondrial dysfunction following TBI may contribute to an exacerbated response in the elderly population.

Aging

Cortical Contusion Injury

Mitochondria

Respiration

Traumatic Brain Injury

Medical Anatomy

Medical Neurobiology

ISCHEMIC COLITIS AS A RESULT OF ABDOMINAL AORTIC ANEURYSMORRHAPHY

Rao, Nandita S, Yoon, Heesuk R, Bray, Sheree A, Allen, Richard C

05 April 2018

Ischemic colitis is a known complication of abdominal aortic aneurysm (AAA) repair. There is still no established consensus regarding the individual significance of factors related to this phenomenon. We detail the hospital course of a patient who unexpectedly developed acute colonic ischemia following open AAA repair. The pathophysiology, diagnostic modalities, potential preventative measures, and effect on patient morbidity and mortality will be presented. Reviewing the current literature, this will focus on the reported statistical importance of various risk factors including the incidence following traditional open repair and endovascular aneurysm repair.

Ischemic

colitis

aneurysm

repair

postoperative

Cardiovascular Diseases

Cardiovascular System

Digestive System

Medical Anatomy

Medical Physiology

Surgery

Case Report: Tension Pneumothorax Complicated by Massive Subcutaneous Emphysema

Grimsley, Christina, Blankenship, Stephen B, MD, FAAEM

05 April 2018

Background: Tension pneumothorax is a condition with frequent fatal complications. This condition is caused by a disruption in the lung - that creates a one-way valve allowing air to accumulate in the pleural space. The fatal complication is the prevention of blood returning to the right side of the heart - due intrathoracic pressure compressing the right atrium. The patient can exhibit symptoms of dyspnea, tachypnea, tracheal deviation, jugular venous distention, subcutaneous emphysema, and shock that can lead to rapid deterioration and death. Case Report: We report a case of massive subcutaneous emphysema complicating tension pneumothorax management. The patient is a 20-year-old male who presented to the emergency department with chest trauma and was in extremis with diffuse severe subcutaneous emphysema. Due to the distorted anatomy, airway management and chest decompression were performed with nonstandard techniques/equipment resulting in rapid patient stabilization. After 4 days in the hospital, he was discharged home with no deficits. Discussion: Many providers do not have the proper equipment or training to treat patients in this extreme condition. CT images demonstrate the anatomical distortions in this case and the increase in size required for invasive life-saving devices. Images demonstrate where many commercial 14 gauge angiocaths and cricothyrotomy kits will not suffice (due to distortion in the anatomy), and these should not be relied on solely. Conclusions: While trauma carts frequently maintain (1.75 - 2 inch) 14 gauge angiocaths, they should also have military grade angiocaths that are 3.25” in length, which will work in most cases. Some, but not all, military-grade cricothyrotomy kits, or individually assembled kits, have 6.0 endotracheal tubes and come with a bougie and cricothyrotomy hook which would have been sufficient in this patient. Prehospital and hospital healthcare personnel should be prepared for similar patient encounters.

Tension Pneumothorax

Subcutaneous Emphysema

Decompression

Emergency Medicine

Equipment and Supplies

Medical Anatomy

Medical Physiology

Trauma

ROLE OF THE REACTIVE OXYGEN SPECIES PEROXYNITRITE IN TRAUMATIC BRAIN INJURY

Deng, Ying

01 January 2008

Reactive oxygen species (ROS) is cytotoxic to the cell and is known to contribute to secondary cell death following primary traumatic brain injury (TBI). We described in our study that PN is the main mediator for both lipid peroxidation and protein nitration, and occurred almost immediately after injury. As a downstream factor to oxidative damage, the peak of Ca2+-dependent, calpainmediated cytoskeletal proteolysis preceded that of neurodegeneration, suggesting that calpain-mediated proteolysis is the common pathway leading to neuronal cell death. The time course study clearly elucidated the interrelationship of these cellular changes following TBI, provided window of opportunity for pharmacological intervention. Furthermore, we conducted a pharmacological study to solidify our hypothesis. First of all, we tested the potency of a membrane permeable, catalytic scavenger of PN-derived free radicals, tempol for its ability to antagonize PN-induced oxidative damage. Tempol successfully inhibited PNinduced protein nitration at dosages of 30, 100 and 300mg/kg. Moreover, early single dose of 300mg/kg was administered and isolated mitochondria were examined for respiratory function and oxidative damage level. Our data showed that tempol reduced mitochondrial oxidative damage, and maintained mitochondrial function within normal limits, which suggested that tempol is efficiently permeable to mitochondrial membrane and mitochondrial oxidative damage is essential to mitochondrial dysfunction. Next, we found that calpainmediated proteolysis is reduced at early treatment with a single dose of tempol. However, the effect of tempol on calpain is short-lived possibly due to systematic elimination. In our multiple dose study, tempol showed a significant inhibitory effect on SBDPs. Consequently, we measured neuordegeneration with the de Olmos aminocupric silver staining method at 7 days post-injury and detected a significant decrease of neuronal cell death. Together, the time course study and pharmacological study strongly support the hypothesis that PN is the upstream mediator in secondary cell death in the CCI TBI mouse model. Moreover, inhibition of PN-mediated oxidative damage with the antioxidant, tempol, is able to attenuate multiple downstream injury mechanisms. However, targeting PN alone may be clinically impractical due to its limited therapeutic window. This limitation may be overcome in future studies by a combination of multiple therapeutic strategies.

Traumatic brain injury

Peroxynitrite

Tempol

Mitochondrial dysfunction

Calpain-Mediated Proteolysis

Medical Anatomy

Medical Neurobiology

Medicine and Health Sciences

THE RELATIONSHIP OF THIGH MUSCLE COMPOSITION AND FAT WITH MUSCLE POWER AND PHYSICAL FUNCTION IN WOMEN WITH KNEE OSTEOARTHRITIS

Davison, Michael J.

January 2014

The aim of this study was to investigate the relationship between thigh intramuscular fat (intraMF) and intermuscular fat (IMF) with quadriceps and hamstrings power and physical performance in women (n=20) with clinical, radiographic knee osteoarthritis (OA). Secondarily, we investigated the correlation between thigh and calf fat volumes, and the agreement between 3.0T and 1.0T MRI for quantifying fat. The thigh and calf of the symptomatic leg were scanned using 3.0T MRI with the IDEAL sequence, and fat separated images were analyzed using semi-automated software to quantify intraMF, IMF and muscle. The calf was also scanned using 1.0T MRI with a Fast Spin Echo (FSE) sequence. Knee extensor and flexor isokinetic power was measured at 20% and 40% of individuals’ maximum voluntary isometric contraction (MVIC) torque, and surface electromyography (EMG) measured activation. We found no relationship between quadriceps or hamstrings intraMF and knee extensor or flexor power, respectively. In addition, there were no relationships between intraMF and performance-based tests. There was a correlation between thigh and calf intraMF (r=0.759; p=0.001) and a trend toward a correlation in IMF (r=0.436; p=0.055). There was agreement and a correlation between calf intraMF (r=0.779; p=0.001) and IMF (r=0.956; p=0.001) using 3.0T and 1.0T MRI. There is disagreement about the relationship of intraMF and quadriceps strength, although studies have found that intraMF is related to decreased physical performance. The importance of calf fat subsets in physical performance of individuals with OA should be further investigated. Power analysis demonstrated a sample size (n=91) is recommended for future investigations of intraMF and power in OA. / Thesis / Master of Science in Medical Sciences (MSMS)

Osteoarthritis

Quadriceps

Hamstrings

Fat

Muscle

Calf

Medical Anatomy

Medical Physiology

Musculoskeletal System

Rheumatology