Air-Gaps via Thermally Decomposable Polymers and Their Application to Compliant Wafer Level Packaging (CWLP)

Kelleher, Hollie Anne

27 January 2005

A method was proposed for the fabrication of air-gaps embedded in dielectric layers using thermally decomposable sacrificial polymers. The research had two main objectives: (1) the development and characterization of air-gap fabrication for use in a wide spectrum of applications; and (2) the integration of air-gaps into a specific application: air-gaps in an integrated circuit compliant wafer level packaging technology, Sea of Leads. Polynorbornene and polycarbonate sacrificial materials were used to form air-gaps at temperatures of 200, 300, and 400oC. Fabrication results of air-gaps encapsulated by both inorganic and organic dielectric materials indicated that the thermal and mechanical properties of the dielectric materials at the decomposition temperature of the sacrificial material resulted in success or failure of the process. Multi-layered encapsulating materials enabled the use of a dielectric material which does not successfully form air-gaps on its own. Thermal decomposition of the sacrificial materials with alteration in the polymer chemistry was studied. Polynorbornene containing 90 mol% butyl and 10 mol% triethoxysilyl side groups was selected as an optimum 400oC decomposition temperature material. The decomposition of this polynobornene composition in an open nitrogen atmosphere was contrasted to decomposition of the polynorbornene while completely encapsulated in a dielectric material. Thermogravimetric analysis and examination of residual surfaces following the decomposition, combined with comparison of the overall kinetic parameters of the decomposition reaction, indicated differences in the two overall processes. The design concept of Sea of Leads three-dimensionally compliant packaging technology with embedded air-gaps is presented. The critical issues resulting from the addition of air-gaps into the process are the compatibility of materials, lithography on topographical features, and yield and uniformity. Factors influencing the z-axis mechanical performance of the air-gap were determined to be the air-gap shape and size, the encapsulating material dielectric properties and thickness, and the decomposition conditions. Model calculations combined with the known limitations of fabrication provided a design space for maximum out-of-plane mechanical movement and compliance of the air-gaps. The results demonstrated that the incorporation of an embedded air-gap in Sea of Leads technology can achieve the necessary z-axis compliance goals for future applications.

Sea of Leads (SoL)

Muhannad S. Bakir

Polynorbornene

Compliant interconnection

Molecular studies of the γ-secretase complex activity and selectivity towards the two substrates APP and Notch

Bakir, Ilyas

January 2010

<p>Alzheimer Disease (AD) is the most common neurodegenerative disorder in the world. One of the neuropathological hallmarks of AD is the senile plaques in the brain. The plaques are mainly composed of the amyloid β (Aβ) peptide. Aβ is generated from the amyloid precursor protein, APP, when it is first cleaved by the β-secretase and subsequently the γ-secretase complex. The γ-secretase complex cleaves at different sites, called γ and ε, where the γ-cleavage site generates Aβ peptides of different lengths and ε-cleavage generates the APP intracellular domain (AICD). The two major forms of Aβ is 40 and 42 amino acids long peptides, where the latter is more prone to aggregate and is the main component in senile plaques. The γ-secretase complex is composed of four proteins; Pen-2, Aph-1, nicastrin and presenilin (PS). The PS protein harbours the catalytic site of the complex, where two aspartate residues in position 257 and 385 (Presenilin 1 numbering) are situated. Most Familial AD (FAD) mutations in the PS gene cause a change in the γ-cleavage site, leading to a shift from producing Aβ40 to the longer more toxic variant Aβ42. Frequently, this often leads to impairments of the AICD production. Another substrate for the γ-secretase complex is Notch. It is important to maintain the Notch signaling since an intracellular domain (NICD) is formed after cleavage by the γ-secretase complex in the membrane (S3-site) and this domain is involved in transcription of genes important for cell fate decisions.</p><p>It has been reported that certain APP luminal juxtamembrane mutations could drastically alter Aβ secretion, however their effect on AICD production remains unknown. In this study we want to analyse wether the juxtamembrane region is important for the AICD production. To gain more insight into the luminal juxtamembrane function for γ-secretase-dependent proteolysis, we have made a juxtamembrane chimeric construct. A four-residue sequence preceding the transmembrane domain (TMD) of APP (GSNK), was replaced by its topological counterpart from the human Notch1 receptor (PPAQ). The resulting chimeric vector C99GVP-PPAQ and the wildtype counterpart were expressed in cells lacking PS1 and PS2 (BD8) together with PS1wt. We observed that the chimeric construct did not alter production of AICD when using a cell based luciferase reporter gene assay monitoring AICD production. We also introduced a PS1 variant lacking a big portion of the large hydrophilic loop, PS1∆exon10, since our group has previously observed that this region affect Aβ production¹⁴³. We found that the absence of the large hydrophilic loop in PS1 gave a 2-fold decrease in AICD-GVP formation from C99GVPwt compared to PS1wt.  The activity of PS1wt and PS1Δexon10 using C99GVP-PPAQ as a substrate gave similar result as the C99GVPwt substrate, i.e. a 2-fold decrease in AICD-GVP formation when comparing PS1Δexon10 with PS1wt. From this data we therefore suggest that the four residues in the juxtramembrane domain (JMD) (GSNK) is not altering ε-cleavage of APP when changed to Notch1 counterpart, PPAQ. Furthermore, we also show that the 2-fold decrease in AICD-production by the PS1Δexon10 molecule is not changed between the two substrates C99GVPwt and C99GVP-PPAQ. This indicates that the luminal region of APP is not directly involved in the ε-site processing. If the luminal region is affecting processing in the γ-cleavage sites, remains however to be investigated.</p>

Alzheimer’s disease

APP

γ-secretase

gamma-secretase

β-amyloid peptide

APP intracellular domain

Notch

Ilyas Bakir

Biochemistry

Biokemi

Molecular studies of the γ-secretase complex activity and selectivity towards the two substrates APP and Notch

Bakir, Ilyas

January 2010

Alzheimer Disease (AD) is the most common neurodegenerative disorder in the world. One of the neuropathological hallmarks of AD is the senile plaques in the brain. The plaques are mainly composed of the amyloid β (Aβ) peptide. Aβ is generated from the amyloid precursor protein, APP, when it is first cleaved by the β-secretase and subsequently the γ-secretase complex. The γ-secretase complex cleaves at different sites, called γ and ε, where the γ-cleavage site generates Aβ peptides of different lengths and ε-cleavage generates the APP intracellular domain (AICD). The two major forms of Aβ is 40 and 42 amino acids long peptides, where the latter is more prone to aggregate and is the main component in senile plaques. The γ-secretase complex is composed of four proteins; Pen-2, Aph-1, nicastrin and presenilin (PS). The PS protein harbours the catalytic site of the complex, where two aspartate residues in position 257 and 385 (Presenilin 1 numbering) are situated. Most Familial AD (FAD) mutations in the PS gene cause a change in the γ-cleavage site, leading to a shift from producing Aβ40 to the longer more toxic variant Aβ42. Frequently, this often leads to impairments of the AICD production. Another substrate for the γ-secretase complex is Notch. It is important to maintain the Notch signaling since an intracellular domain (NICD) is formed after cleavage by the γ-secretase complex in the membrane (S3-site) and this domain is involved in transcription of genes important for cell fate decisions. It has been reported that certain APP luminal juxtamembrane mutations could drastically alter Aβ secretion, however their effect on AICD production remains unknown. In this study we want to analyse wether the juxtamembrane region is important for the AICD production. To gain more insight into the luminal juxtamembrane function for γ-secretase-dependent proteolysis, we have made a juxtamembrane chimeric construct. A four-residue sequence preceding the transmembrane domain (TMD) of APP (GSNK), was replaced by its topological counterpart from the human Notch1 receptor (PPAQ). The resulting chimeric vector C99GVP-PPAQ and the wildtype counterpart were expressed in cells lacking PS1 and PS2 (BD8) together with PS1wt. We observed that the chimeric construct did not alter production of AICD when using a cell based luciferase reporter gene assay monitoring AICD production. We also introduced a PS1 variant lacking a big portion of the large hydrophilic loop, PS1∆exon10, since our group has previously observed that this region affect Aβ production143. We found that the absence of the large hydrophilic loop in PS1 gave a 2-fold decrease in AICD-GVP formation from C99GVPwt compared to PS1wt.  The activity of PS1wt and PS1Δexon10 using C99GVP-PPAQ as a substrate gave similar result as the C99GVPwt substrate, i.e. a 2-fold decrease in AICD-GVP formation when comparing PS1Δexon10 with PS1wt. From this data we therefore suggest that the four residues in the juxtramembrane domain (JMD) (GSNK) is not altering ε-cleavage of APP when changed to Notch1 counterpart, PPAQ. Furthermore, we also show that the 2-fold decrease in AICD-production by the PS1Δexon10 molecule is not changed between the two substrates C99GVPwt and C99GVP-PPAQ. This indicates that the luminal region of APP is not directly involved in the ε-site processing. If the luminal region is affecting processing in the γ-cleavage sites, remains however to be investigated.

Alzheimer’s disease

APP

γ-secretase

gamma-secretase

β-amyloid peptide

APP intracellular domain

Notch

Ilyas Bakir

Biochemistry

Biokemi